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2024-11-02 10:04:20 -04:00 · 2024-11-02 10:04:20 -04:00 · 583b24274c
commit 583b24274c
parent 1e20814685
3 changed files with 588 additions and 50 deletions
--- a/Midterm_submittion.py
+++ b/Midterm_submittion.py
@ -0,0 +1,445 @@
 #!/usr/bin/env python
 # coding: utf-8
 import numpy as np
 import math
 import imageio
 import time
 import random
 import cython
 """
 This class allows us to manipulate vectors
 Not all of the functions are used yet - but they might be later when we start adding things
 """
@cython.cclass
 class Vec3:
    v = cython.declare(cython.float[3],visibility="public")
    def __cinit__(self, x:cython.double =0, y:cython.double=0, z:cython.double=0):
        self.v:cython.float[3] = [x, y, z]
    def __init__(self, x:cython.double =0, y:cython.double=0, z:cython.double=0):
        self.v:cython.float[3] = [x, y, z]
    def __add__(self, other):
        return Vec3(self.v[0] + other.v[0],self.v[1] + other.v[1],self.v[2] + other.v[2],)
    def __sub__(self, other):
        return Vec3(self.v[0] - other.v[0],self.v[1] - other.v[1],self.v[2] - other.v[2],)
    def __mul__(self, other):
        if isinstance(other, Vec3):
            return Vec3(self.v[0] * other.v[0],self.v[1] * other.v[1],self.v[2] * other.v[2],)
        elif isinstance(other, (int, float)):
            return Vec3(self.v[0] * other,self.v[1] * other,self.v[2] * other,)
        raise TypeError("Can only multiply by a Vec3 or scalar (int or float).")
    @cython.cfunc
    def __truediv__(self, scalar):
        if scalar == 0:
            raise ValueError("Cannot divide by zero.")
        return Vec3(*(self.v[i] / scalar for i in range(3)))
    def length(self)->cython.float:
        return math.sqrt(self.v[0]**2 + self.v[1]**2 + self.v[2]**2)
    @cython.cfunc
    def normalize(self):
        length = self.length()
        return self / length if length > 0 else Vec3()
    def to_tuple(self):
        return (self.v[0],self.v[1],self.v[2])
    def __repr__(self):
        return f"Vec3({self.v[0]}, {self.v[1]}, {self.v[2]})"
    @cython.cfunc
    def dot(self, other):
        return self.v[0]* other.v[0]+self.v[1]* other.v[1]+self.v[2]* other.v[2]
 """
 Here we will be calculating what the value for n is based on T, P, but we will
 also be taking dispersion into account - remember, we are considering 440 nm, 550 nm, 680 nm
 These equations match the tabulated results made by Penndorf
 """
 wavelengths = Vec3(0.68, 0.55, 0.44)  # These are the wavelengths in um
 # The n_s values gives us the different refractive indices for the different wavelenghts
 # The n values give us the new refractive indices depending on the temperature and pressure
@cython.cfunc
 def refraction_calculator(T:cython.int, P:cython.int) -> tuple[Vec3, Vec3]:
    alpha:cython.float = 0.00367  # in inverse Celsius
    t_s:cython.int = 15  # degrees Celsius
    p_s:cython.int = 760  # mmHg
    n_s_values = []  # for debugging / comparing to the internet values
    n_values = []
    n_s:cython.double
    n:cython.double
    i:cython.int
    for i in [wavelengths.v[0], wavelengths.v[1], wavelengths.v[2]]:
        n_s = 1 + (0.05792105 / (238.0185 - i**-2) + 0.00167917 / (57.362 - i**-2))
        n = ((n_s - 1) * ((1 + alpha * t_s) / (1 + alpha * T)) * (P / p_s)) + 1
        n_s_values.append(n_s)
        n_values.append(n)
    return Vec3(*n_s_values), Vec3(*n_values)
@cython.cfunc
 def beta(n_values:Vec3):
    N_s:cython.double = 2.54743e7  # um^-3
    beta_values = []
    for i, n in enumerate(n_values.v):
        wavelength = wavelengths.v[i]  # Corresponding wavelength value
        beta_1 = ((8 * math.pi * (n**2 - 1)**2) / ((2 * N_s) * (wavelength)**4))*1e6  # The whole thing should be in m^-1 to match with the rest of the code
        beta = (beta_1*10)
        beta_values.append(beta)
    return Vec3(beta_values[0],beta_values[1],beta_values[2])
 # Example usage, normal is 25, 750
 T:cython.int = 5  # Temperature in degrees Celsius
 P:cython.int = 760  # Pressure in mmHg
 n_s_values:Vec3
 n_values:cython.double
 n_s_values, n_values = refraction_calculator(T, P)
 beta_values = beta(n_values)
 #print("n_s values:", refraction_calculator_result.v)
 #print("n values:", n_values.v)
 #print("Beta values:", beta_values.v)
 # In[7]:
 """
 Here we are able to change the sun's direction - once the GUI is in place, this will be done from there
 """
 kInfinity = float('inf')
 angle_degrees:cython.int = 90  # Sun direction in degrees (0 to 90, noon to sunset)
 angle_radians:cython.double = math.radians(angle_degrees)  # Convert to radians
 sunDir:Vec3 = Vec3(0, math.cos(angle_radians), -math.sin(angle_radians))
 """
 The betaR values come from the previous cell
 """
 #betaR = Vec3(3.8e-6, 13.5e-6, 33.1e-6), this is what the Nishita paper used
 betaR = Vec3(*beta_values.v)  # Keeps it as a Vec3
 """
 There are many "categories" of aerosols and each has their own extinction coefficient (I removed the factor of 1.1)
 Continental Clean - 26e-6     g = 0.709
 Continental Average - 75e-6   g = 0.703
 Continental Polluted - 175e-6 g = 0.698
 Urban - 353e-6                g = 0.689
 Desert - 145e-6               g = 0.729
 Maritime Clean - 90e-6        g = 0.772
 Maritime Polluted - 115e-6    g = 0.756
 Maritime Tropic - 43e-6       g = 0.774
 Arctic - 23e-6                g = 0.721
 Antarctic - 11e-6             g = 0.784
 """
 betaM = Vec3(11e-6, 11e-6, 11e-6) # We need to have the Mie scattering be the same in all the directions
 # The greater the value of beta, the smaller the Mie scattering point (responsable for the halo around the sun)
 # If there is more pollution, we get a larger halo and the colors of the sunset become desaturated (more hazy)
 # Default is 21e-6
 # For the value of betaM, we also need to change the anisotropy factor. This is in the same paper. 
 g = 0.784
 """
 The atmosphere model we use is as follows, with the radii and the scale heights
 """
 earthRadius:cython.int = 6360e3 #m
 atmosphereRadius:cython.int = 6420e3 #m (60 km higher than earth)
 Hr:cython.int = 7994
 Hm:cython.int = 1200
 # In[8]:
 """
 This is the compute incident light funciton from Nishita's paper
 We translated it to Python and then are using cython to make it go faster
 This is all explained in more detail in the submitted PDF
 """
@cython.cfunc
 def computeIncidentLight(direction:Vec3) -> tuple[float,float,float]:
    tmin:cython.float=0
    tmax:cython.float=kInfinity
    # We can change the origin position if we want, but for now it is 1 meter above the surface
    orig:Vec3 = Vec3(0, earthRadius + 1, 0)
    t0:cython.float
    t1:cython.float
    t0, t1 = raySphereIntersect(orig, direction, atmosphereRadius)
    if t1 < 0:
        return Vec3(0, 0, 0)
    if t0 > tmin and t0 > 0:
        tmin = t0
    if t1 < tmax:
        tmax = t1
    numSamples:int = 16
    numSamplesLight:int = 8
    segmentLength = (tmax - tmin) / numSamples
    tCurrent = tmin
    sumR = Vec3()
    sumM = Vec3()
    opticalDepthR = 0
    opticalDepthM = 0
    mu:cython.float = direction.dot(sunDir) # This is the cosine of the angle between the direction vector (V) and the sun Direction
    """
    Phase functions - the anisotropy factor depends on the Mie scattering we have chosen, it is defined in the previous cell
    """
    phaseR = (3 * (1 + (mu * mu))) / (16 * math.pi)
    phaseM = 3 / (8 * math.pi) * ((1 - g * g) * (1 + mu * mu)) / ((2 + g * g) * ((1 + g * g - 2 * g * mu) ** 1.5))
    i:cython.int
    for i in range(numSamples):
        samplePosition = orig + direction * (tCurrent + segmentLength * 0.5)
        height = samplePosition.length() - earthRadius
        hr = math.exp(-height / Hr) * segmentLength
        hm = math.exp(-height / Hm) * segmentLength
        opticalDepthR += hr
        opticalDepthM += hm
        # Sample position is the start, but it should be in the direction of the sun
        t0Light, t1Light = raySphereIntersect(samplePosition, sunDir, atmosphereRadius)
        if t1Light < 0:
            continue
        segmentLengthLight = (t1Light - t0Light) / numSamplesLight
        tCurrentLight = 0
        opticalDepthLightR = 0
        opticalDepthLightM = 0
        j:cython.int
        for j in range(numSamplesLight):
            samplePositionLight = samplePosition + (sunDir * (tCurrentLight + segmentLengthLight * 0.5))
            heightLight = samplePositionLight.length() - earthRadius
            if heightLight < 0:
                break
            opticalDepthLightR += (math.exp(-heightLight / Hr) * segmentLengthLight)
            opticalDepthLightM += (math.exp(-heightLight / Hm) * segmentLengthLight)
            tCurrentLight += segmentLengthLight
        if j == numSamplesLight - 1:
            tau = (betaR * (opticalDepthR + opticalDepthLightR)) + (betaM * (opticalDepthM + opticalDepthLightM))
            attenuation = Vec3(math.exp(-tau.v[0]), math.exp(-tau.v[1]), math.exp(-tau.v[2]))
            sumR += (attenuation * hr)
            sumM += (attenuation * hm)
        tCurrent += (segmentLength)
    # Changing the * 20 number just changes the intensity os the light, it does not much change the colors themselves, this is the "magic number" Nishita used
    final_color = (sumR * betaR * phaseR + sumM * betaM * phaseM) * 20 
    return final_color.to_tuple()
 # In[9]:
 """
 These are complimentary functions that are used to solve the intensity of light. Again, from nishita's paper
 """
@cython.cfunc
 def raySphereIntersect(orig:Vec3, direction:Vec3, radius:cython.double) -> tuple[cython.float,cython.float]:
    A:cython.double = direction.v[0]**2 + direction.v[1]**2 +direction.v[2]**2
    B:cython.double = 2 * (direction.v[0]*orig.v[0] +direction.v[1]*orig.v[1] +direction.v[2]*orig.v[2] )
    C:cython.double = orig.v[0]**2 + orig.v[1]**2 +orig.v[2]**2 - radius ** 2
    t0: cython.float
    t1: cython.float
    t0, t1 = solveQuadratic(A, B, C)
    if t1 < 0:
        return (kInfinity, kInfinity)
    if t0 > t1:
        t0, t1 = t1, t0
    return (t0, t1)
@cython.cfunc
 def solveQuadratic(a:cython.double, b:cython.double, c:cython.double) -> tuple[cython.float,cython.float]:
    if b == 0:
        if a == 0:
            return (0, 0)
        x1 = 0
        x2 = math.sqrt(-c / a)
        return (x1, x2)
    discr = b ** 2 - 4 * a * c
    if discr < 0:
        return (kInfinity, kInfinity)
    q = (-0.5 * (b - np.sqrt(discr))) if b < 0 else (-0.5 * (b + np.sqrt(discr)))
    x1 = q / a
    x2 = c / q
    return (x1, x2)
 # In[10]:
 """
 Rendering Skydome image
 """
@cython.cfunc
 def renderSkydome(filename):
    width:cython.int
    height:cython.int
    width, height = 256,256
    image = np.zeros((height, width, 3), dtype=float)
    start_time = time.time()  # Start timing
    j:cython.int
    i:cython.int
    x:cython.float
    y:cython.float
    z2:cython.float
    phi:float
    theta:float
    direction:Vec3
    for j in range(height):
        for i in range(width):
            x = 2 * (i + 0.5) / (width - 1) - 1
            y = 2 * (j + 0.5) / (height - 1) - 1
            z2 = x * x + y * y
            if z2 <= 1:
                phi = math.atan2(y, x)
                theta = math.acos(1 - z2)
                # This changes for each pixel
                direction = Vec3(math.sin(theta) * math.cos(phi), math.cos(theta), math.sin(theta) * math.sin(phi))
                color = computeIncidentLight(direction)
                #color = computeIncidentLight(direction)
                # Assign the clipped color directly to the image array
                image[j][i][0] = np.clip(color, 0, 1)[0]
                image[j][i][1] = np.clip(color, 0, 1)[1]
                image[j][i][2] = np.clip(color, 0, 1)[2]
        # Print elapsed time after each row
        elapsed_time = time.time() - start_time
        print(f"Rendering row {j + 1}/{height}, elapsed time: {elapsed_time:.2f} seconds")
        #print(f"Rendering row {j + 1}/{height}")
    # Save result to a PNG image
    image = np.clip(image, 0, 1) * 255 # change 255
    imageio.imwrite(filename, image.astype(np.uint8))
 # In[11]:
 """
 Rendering camera image
 """
 def renderFromCamera(filename: str):
    width: cython.int = 252
    height: cython.int = 252
    image = np.zeros((height, width, 3), dtype=np.float32)
    aspectRatio: cython.float = width / float(height)
    fov: cython.float = 65.0  # Field of view
    angle: cython.float = np.tan(fov * np.pi / 180 * 0.5)  # Camera's view angle
    start_time = time.time()  # Start timing
    numPixelSamples: cython.int = 4
    y: cython.int
    x: cython.int
    m: cython.int
    n: cython.int
    rayx: cython.float
    rayy: cython.float
    direction: Vec3
    color: tuple  # Assuming computeIncidentLight returns a tuple
    for y in range(height):
        for x in range(width):
            sum_color = np.zeros(3, dtype=np.float32)  # Use numpy array for accumulation
            for m in range(numPixelSamples):
                for n in range(numPixelSamples):
                    # Compute ray direction with jitter
                    rayx = (2 * (x + (m + random.uniform(0, 1)) / numPixelSamples) / float(width) - 1) * aspectRatio * angle
                    rayy = (1 - (y + (n + random.uniform(0, 1)) / numPixelSamples) / float(height) * 2) * angle
                    # Create the direction vector and normalize it
                    direction = Vec3(rayx, rayy, -1).normalize()
                    color = computeIncidentLight(direction)  # Assuming this returns a tuple
                    # Accumulate color values
                    sum_color[0] += color[0]
                    sum_color[1] += color[1]
                    sum_color[2] += color[2]
            # Average the accumulated color and clip to [0, 1]
            image[y, x] = np.clip(sum_color / (numPixelSamples * numPixelSamples), 0, 1)
        # Print elapsed time after each row
        elapsed_time = time.time() - start_time
        print(f"Rendering row {y + 1}/{height}, elapsed time: {elapsed_time:.2f} seconds")
    # Save the result to a PNG image
    image = np.clip(image, 0, 1) * 255
    imageio.imwrite(filename, image.astype(np.uint8))
 # In[12]:
 """
 Testing
 """
 renderSkydome("test.png")
 # In[ ]:
--- a/app.py
+++ b/app.py
@ -13,89 +13,181 @@ def get_api_params(coords):
 # create tkinter window
 root_tk = tkinter.Tk()
 root_tk.geometry(f"{1000}x{700}")
 root_tk.title("map_view_simple_example.py")
 # create map widget
 map_widget = tkintermapview.TkinterMapView(root_tk, width=1000, height=700, corner_radius=0)
 map_widget.pack(fill="both", expand=True)
 # set other tile server (standard is OpenStreetMap)
 # map_widget.set_tile_server("https://mt0.google.com/vt/lyrs=m&hl=en&x={x}&y={y}&z={z}&s=Ga", max_zoom=22)  # google normal
 # map_widget.set_tile_server("https://mt0.google.com/vt/lyrs=s&hl=en&x={x}&y={y}&z={z}&s=Ga", max_zoom=22)  # google satellite
 def printer():
    print("button")
 environment_tk = tkinter.Tk()
 class renderedImageZoom:
-    def __init__(self,root,coords):
+    def __init__(self,root,image_window,aerosol_window):
-        self.image_window = root
+        self.root = root
        self.root.geometry(f"{1000}x{700}")
        self.root.title("map_view_simple_example.py")
        self.aerosol_window = aerosol_window
 # create map widget
        self.map_widget = tkintermapview.TkinterMapView(self.root, width=1000, height=700, corner_radius=0)
        self.map_widget.pack(fill="both", expand=True)
        self.map_widget.add_right_click_menu_command(label="Set as observer location",
                                                command=self.add_marker_event,
                                                pass_coords=True)
        self.map_widget.add_right_click_menu_command(label="get altitude",
                                                command=self.get_altitude,
                                                pass_coords=True)
        #self.map_widget.add_right_click_menu_command(label="open_window",
        #                                        command=self.show_image,
        #                                        pass_coords=True)
        self.aerosol_window.title("options selector")
        environemnt_info_text = tkinter.Label(self.aerosol_window, text="Please choose in which environment the sunset is occuring")
        environemnt_info_text.pack(side='top',pady=20,padx=10)
 #Continental Clean - 26e-6       g = 0.709
 #Continental Average - 75e-6     g = 0.703
 #Continental Polluted - 175e-6   g = 0.698
 #                                          
 #Urban - 353e-6                  g = 0.689
 #                                          
 #Desert - 145e-6                 g = 0.729
 #                                          
 #Maritime Clean - 90e-6          g = 0.772
 #Maritime Polluted - 115e-6      g = 0.756
 #Maritime Tropic - 43e-6         g = 0.774
 #                                          
 #Arctic - 23e-6                  g = 0.721
 #                                          
 #Antarctic - 11e-6               g = 0.784
        buton_cont_clean = tkinter.Button(self.aerosol_window,text="Continental Clean",command=lambda: self.env_setter(26e-6,0.709));
        buton_cont_clean.pack(side='top',padx=10,pady=5)
        buton_cont_avr = tkinter.Button(self.aerosol_window,text="Continental Average ",command=lambda: self.env_setter(75e-6,0.793));
        buton_cont_avr.pack(side='top',padx=10,pady=5)
        buton_cont_poll = tkinter.Button(self.aerosol_window,text="Continental Polluted ",command=lambda: self.env_setter(175e-6,0.698));
        buton_cont_poll.pack(side='top',padx=10,pady=5)
        buton_urban = tkinter.Button(self.aerosol_window,text="Urban ",command=lambda: self.env_setter(353e-6,0.689));
        buton_urban.pack(side='top',padx=10,pady=5)
        buton_desert = tkinter.Button(self.aerosol_window,text="Desert ",command=lambda: self.env_setter(145e-6,0.729));
        buton_desert.pack(side='top',padx=10,pady=5)
        buton_mar_clean = tkinter.Button(self.aerosol_window,text="Maritime Clean ",command=lambda: self.env_setter(90e-6,0.772));
        buton_mar_clean.pack(side='top',padx=10,pady=5)
        buton_mar_poll = tkinter.Button(self.aerosol_window,text="Maritime Polluted ",command=lambda: self.env_setter(115e-6,0.756));
        buton_mar_poll.pack(side='top',padx=10,pady=5)
        buton_mar_tro = tkinter.Button(self.aerosol_window,text="Maritime Tropic ",command=lambda: self.env_setter(43e-6,0.774));
        buton_mar_tro.pack(side='top',padx=10,pady=5)
        buton_arctic = tkinter.Button(self.aerosol_window,text="Arctic ",command=lambda: self.env_setter(23e-6,0.721));
        buton_arctic.pack(side='top',padx=10,pady=5)
        buton_antarctic = tkinter.Button(self.aerosol_window,text="Antarctic ",command=lambda: self.env_setter(11e-6,0.784));
        buton_antarctic.pack(side='top',padx=10,pady=5)
        self.image_window = image_window
        self.image_window.title("Simulated Sunset")
        self.image_window.config(width=256,height=256)
-        image = skydome.renderFromCamera(coords)
+        #image = skydome.renderFromCamera(coords)
        self.canvas = tkinter.Canvas(self.image_window,bg="white")
        self.canvas.pack(fill=tkinter.BOTH,expand=True)
        #self.img = Image.fromarray(image,mode="RGB")
        #self.tk_image = ImageTk.PhotoImage(width=256,height=256,image=self.img)
        #img = ImageTk.PhotoImage(Image.open("highpress_camera.png"))
        #self.canvas.create_image(0,0, anchor="center", image=self.tk_image)
        zoom_in_button = tkinter.Button(self.image_window, text="Zoom In", command=self.zoom_in)
        zoom_out_button = tkinter.Button(self.image_window, text="Zoom Out", command=self.zoom_out)
        render_button = tkinter.Button(self.image_window,text="render",command=self.render)
        zoom_in_button.pack(side=tkinter.LEFT)
        zoom_out_button.pack(side=tkinter.LEFT)
        render_button.pack(side=tkinter.RIGHT)
        self.canvas.bind("<Button-4>",self.zoom_in)
        self.canvas.bind("<Button-5>", self.zoom_out)
    def env_setter(self,environment_constant,g):
        self.betaM = skydome.Vec3(environment_constant,environment_constant,environment_constant)
        self.g = g
    def render(self):
        image = skydome.renderFromCamera(self.coords,self.betaM,self.g,self.altitude)
        self.img = Image.fromarray(image,mode="RGB")
        self.tk_image = ImageTk.PhotoImage(width=256,height=256,image=self.img)
        #img = ImageTk.PhotoImage(Image.open("highpress_camera.png"))
        self.canvas.create_image(0,0, anchor="nw", image=self.tk_image)
        zoom_in_button = tkinter.Button(self.image_window, text="Zoom In", command=self.zoom_in)
        zoom_out_button = tkinter.Button(self.image_window, text="Zoom Out", command=self.zoom_out)
        zoom_in_button.pack(side=tkinter.LEFT)
        zoom_out_button.pack(side=tkinter.LEFT)
-        self.canvas.bind("<Button-4>",self.zoom_in)
+    
        self.canvas.bind("<Button-5>", self.zoom_out)
    def zoom_in(self, event=None):
        # Increase the image size by a factor (e.g., 1.2)
        self.img = self.img.resize((int(self.img.width * 1.2), int(self.img.height * 1.2)))
        self.tk_image = ImageTk.PhotoImage(self.img)
        self.canvas.delete("all")
-        self.canvas.create_image(0, 0, anchor=tkinter.NW, image=self.tk_image)
+        self.canvas.create_image(0, 0, anchor="nw", image=self.tk_image)
    def zoom_out(self, event=None):
        # Decrease the image size by a factor (e.g., 0.8)
        self.img = self.img.resize((int(self.img.width * 0.8), int(self.img.height * 0.8)))#,resampling)
        self.tk_image = ImageTk.PhotoImage(self.img)
        self.canvas.delete("all")
-        self.canvas.create_image(0, 0, anchor=tkinter.NW, image=self.tk_image)
+        self.canvas.create_image(0, 0, anchor="nw", image=self.tk_image)
-def show_image(coords):
+#    def show_image(self,coords):
-    image_window = tkinter.Toplevel()
+#        self.coords = coords
        #image_shower = renderedImageZoom(image_window,coords)
 #        self.image_window.mainloop()
-    image_shower = renderedImageZoom(image_window,coords)
+    def add_marker_event(self,coords):
-    image_window.mainloop()
+        self.coords = coords
        print("marker added to {}".format(self.coords))
        self.map_widget.delete_all_marker()
        new_marker = self.map_widget.set_marker(self.coords[0], self.coords[1], text="sunset observer")
        self.get_altitude(coords)
-def marker_click(marker):
+    def marker_click(self,marker):
-    print(f"marker clicked - text: {marker.text}  position: {marker.position}")
+        print(f"marker clicked - text: {marker.text}  position: {marker.position}")
 def add_marker_event(coords):
    print("marker added to {}".format(coords))
    map_widget.delete_all_marker()
    new_marker = map_widget.set_marker(coords[0], coords[1], text="sunset observer")
-def get_altitude(coords):
+    def get_altitude(self,coords):
-    print("getting altitude for {}\n".format(coords))
+        self.coords = coords
-    params = get_api_params(coords)
+        print("getting altitude for {}\n".format(self.coords))
-    r = requests.get(URL,params)
+        params = get_api_params(self.coords)
-    data = r.json()
+        r = requests.get(URL,params)
-    print(data['results'][0]['elevation'])
+        data = r.json()
        print(data['results'][0]['elevation'])
        self.altitude = data['results'][0]['elevation']
 map_widget.add_right_click_menu_command(label="Set as observer location",
                                        command=add_marker_event,
                                        pass_coords=True)
 map_widget.add_right_click_menu_command(label="get altitude",
                                        command=get_altitude,
                                        pass_coords=True)
-map_widget.add_right_click_menu_command(label="open_window",
+
-                                        command=show_image,
+image_window = tkinter.Toplevel()
-                                        pass_coords=True)
+
 #image_shower = renderedImageZoom(image_window,coords)
 image_shower = renderedImageZoom(root_tk,image_window,environment_tk)
 root_tk.mainloop()
--- a/skydome.py
+++ b/skydome.py
@ -222,7 +222,7 @@ Antarctic - 11e-6
 """
-betaM = Vec3(21e-6, 21e-6, 21e-6) # We need to have the Mie scattering be the same in all the directions
+#betaM = Vec3(21e-6, 21e-6, 21e-6) # We need to have the Mie scattering be the same in all the directions
 # The greater the value of beta, the smaller the Mie scattering point (responsable for the halo around the sun)
 # If there is more pollution, we get a larger halo and the colors of the sunset become desaturated (more hazy)
 # Default is 21e-6
@ -235,12 +235,12 @@ Hm:cython.int = 1200
 # The direction will change for each pixel
@cython.cfunc
-def computeIncidentLight(direction:Vec3) -> tuple[float,float,float]:
+def computeIncidentLight(direction:Vec3,betaM,g,observerEarthRadius) -> tuple[float,float,float]:
    tmin:cython.float=0
    tmax:cython.float=kInfinity
    # We can change the origin position if we want, but for now it is 1 meter above the surface
-    orig:Vec3 = Vec3(0, earthRadius + 1, 0)
+    orig:Vec3 = Vec3(0, observerEarthRadius + 1, 0)
    t0:cython.float
    t1:cython.float
    t0, t1 = raySphereIntersect(orig, direction, atmosphereRadius)
@ -262,13 +262,13 @@ def computeIncidentLight(direction:Vec3) -> tuple[float,float,float]:
    mu:cython.float = direction.dot(sunDir) # This is the cosine of the angle between the direction vector (V) and the sun Direction
    phaseR = (3 * (1 + (mu * mu))) / (16 * math.pi)
-    g = 0.76
+    #g = 0.76
    phaseM = 3 / (8 * math.pi) * ((1 - g * g) * (1 + mu * mu)) / ((2 + g * g) * ((1 + g * g - 2 * g * mu) ** 1.5))
    i:cython.int
    for i in range(numSamples):
        samplePosition = orig + direction * (tCurrent + segmentLength * 0.5)
-        height = samplePosition.length() - earthRadius
+        height = samplePosition.length() - observerEarthRadius
        hr = math.exp(-height / Hr) * segmentLength
        hm = math.exp(-height / Hm) * segmentLength
        opticalDepthR += hr
@ -288,7 +288,7 @@ def computeIncidentLight(direction:Vec3) -> tuple[float,float,float]:
        j:cython.int
        for j in range(numSamplesLight):
            samplePositionLight = samplePosition + (sunDir * (tCurrentLight + segmentLengthLight * 0.5))
-            heightLight = samplePositionLight.length() - earthRadius
+            heightLight = samplePositionLight.length() - observerEarthRadius
            if heightLight < 0:
                break
            opticalDepthLightR += (math.exp(-heightLight / Hr) * segmentLengthLight)
@ -389,8 +389,9 @@ def renderSkydome(filename):
-def renderFromCamera(filename):
+def renderFromCamera(filename,betaM,g,altitude):
    observerEarthRadius = earthRadius + altitude
    width:cython.int
    height:cython.int
    width, height = 100, 100
@ -420,7 +421,7 @@ def renderFromCamera(filename):
            #This changes for each pixel, it is the direction we are looking in
            direction = Vec3(rayx, rayy, -1).normalize()
-            color = computeIncidentLight(direction)
+            color = computeIncidentLight(direction,betaM,g,observerEarthRadius)
            #image[y, x] = np.array(color)
            image[y][x] = np.clip(color, 0, 1)