8

In the plotly website Map Configuration and Styling in Python is described how to automatically zoom a "Geo map":

import plotly.express as px

fig = px.line_geo(lat=[0,15,20,35], lon=[5,10,25,30])            # Creates a "Geo map" figure
fig.update_geos(fitbounds="locations")                           # Automatic Zooming !!!!
fig.show()

and this works, moreover if I try to the same on a "Mapbox map" it does not apply auto zoom:

fig = px.scatter_mapbox(filtered_df, lat="latitude", lon="longitude", color="ID")  # Creates a "Mapbox map" figure
fig.update_layout(mapbox_style="open-street-map")
fig.update_geos(fitbounds="locations")                                             # Automatic Zooming not working!!!

There is not information of how to do it in the Mapbox Map Layers in Python.

1
  • In order for your code to be reproducible, can you include filtered_df?
    – Derek O
    Sep 8, 2020 at 5:35

4 Answers 4

7

I wrote my own function along with other geojson compatible functions in rv_geojson.py

It takes a list of locations and finds the geometric height and width of the rectangular binding box, good for using with mercator projection. It returns zoom and center.

def zoom_center(lons: tuple=None, lats: tuple=None, lonlats: tuple=None,
        format: str='lonlat', projection: str='mercator',
        width_to_height: float=2.0) -> (float, dict):
    """Finds optimal zoom and centering for a plotly mapbox.
    Must be passed (lons & lats) or lonlats.
    Temporary solution awaiting official implementation, see:
    https://github.com/plotly/plotly.js/issues/3434
    
    Parameters
    --------
    lons: tuple, optional, longitude component of each location
    lats: tuple, optional, latitude component of each location
    lonlats: tuple, optional, gps locations
    format: str, specifying the order of longitud and latitude dimensions,
        expected values: 'lonlat' or 'latlon', only used if passed lonlats
    projection: str, only accepting 'mercator' at the moment,
        raises `NotImplementedError` if other is passed
    width_to_height: float, expected ratio of final graph's with to height,
        used to select the constrained axis.
    
    Returns
    --------
    zoom: float, from 1 to 20
    center: dict, gps position with 'lon' and 'lat' keys

    >>> print(zoom_center((-109.031387, -103.385460),
    ...     (25.587101, 31.784620)))
    (5.75, {'lon': -106.208423, 'lat': 28.685861})
    """
    if lons is None and lats is None:
        if isinstance(lonlats, tuple):
            lons, lats = zip(*lonlats)
        else:
            raise ValueError(
                'Must pass lons & lats or lonlats'
            )
    
    maxlon, minlon = max(lons), min(lons)
    maxlat, minlat = max(lats), min(lats)
    center = {
        'lon': round((maxlon + minlon) / 2, 6),
        'lat': round((maxlat + minlat) / 2, 6)
    }
    
    # longitudinal range by zoom level (20 to 1)
    # in degrees, if centered at equator
    lon_zoom_range = np.array([
        0.0007, 0.0014, 0.003, 0.006, 0.012, 0.024, 0.048, 0.096,
        0.192, 0.3712, 0.768, 1.536, 3.072, 6.144, 11.8784, 23.7568,
        47.5136, 98.304, 190.0544, 360.0
    ])
    
    if projection == 'mercator':
        margin = 1.2
        height = (maxlat - minlat) * margin * width_to_height
        width = (maxlon - minlon) * margin
        lon_zoom = np.interp(width , lon_zoom_range, range(20, 0, -1))
        lat_zoom = np.interp(height, lon_zoom_range, range(20, 0, -1))
        zoom = round(min(lon_zoom, lat_zoom), 2)
    else:
        raise NotImplementedError(
            f'{projection} projection is not implemented'
        )
    
    return zoom, center

Use it as

zoom, center = zoom_center(
    lons=[5, 10, 25, 30],
    lats=[0, 15, 20, 35]
)
fig = px.scatter_mapbox(
    filtered_df, lat="latitude", lon="longitude", color="ID",
    zoom=zoom, center=center
)  # Creates a "Mapbox map" figure

7

The Mapbox API documentation shows that zooms are essentially on a log scale. So after some trial and error the following function worked for me:

max_bound = max(abs(x1-x2), abs(y1-y2)) * 111
zoom = 11.5 - np.log(max_bound)

Notes:

  • In this example, the xy (lon/lat) coordinates are in decimal degrees
  • The 111 is a constant to convert decimal degrees to kilometers
  • The value of 11.5 worked for my desired level of zoom/cropping, but I first experimented with values between 10-12
1
  • Working on small scale (map ~ 20km wide), instead of 11.5 I use 15. Great workaround! Thanks
    – Alex Poca
    Apr 27, 2022 at 8:23
0

Based on this question on plotly.com with the first version of the function below I came up with the following final solution:

def get_plotting_zoom_level_and_center_coordinates_from_lonlat_tuples(
        longitudes=None, latitudes=None, lonlat_pairs=None):
    """Function documentation:\n
    Basic framework adopted from Krichardson under the following thread:
    https://community.plotly.com/t/dynamic-zoom-for-mapbox/32658/6

    # NOTE:
    # THIS IS A TEMPORARY SOLUTION UNTIL THE DASH TEAM IMPLEMENTS DYNAMIC ZOOM
    # in their plotly-functions associated with mapbox, such as go.Densitymapbox() etc.

    Returns the appropriate zoom-level for these plotly-mapbox-graphics along with
    the center coordinate tuple of all provided coordinate tuples.
    """

    # Check whether the list hasn't already be prepared outside this function
    if lonlat_pairs is None:
        # Check whether both latitudes and longitudes have been passed,
        # or if the list lenghts don't match
        if ((latitudes is None or longitudes is None)
                or (len(latitudes) != len(longitudes))):
            # Otherwise, return the default values of 0 zoom and the coordinate origin as center point
            return 0, (0, 0)

        # Instantiate collator list for all coordinate-tuples
        lonlat_pairs = [(longitudes[i], latitudes[i]) for i in range(len(longitudes))]

    # Get the boundary-box via the planar-module
    b_box = planar.BoundingBox(lonlat_pairs)

    # In case the resulting b_box is empty, return the default 0-values as well
    if b_box.is_empty:
        return 0, (0, 0)

    # Otherwise, get the area of the bounding box in order to calculate a zoom-level
    area = b_box.height * b_box.width

    # * 1D-linear interpolation with numpy:
    # - Pass the area as the only x-value and not as a list, in order to return a scalar as well
    # - The x-points "xp" should be in parts in comparable order of magnitude of the given area
    # - The zoom-levels are adapted to the areas, i.e. start with the smallest area possible of 0
    # which leads to the highest possible zoom value 20, and so forth decreasing with increasing areas
    # as these variables are antiproportional
    zoom = np.interp(x=area,
                     xp=[0, 5**-10, 4**-10, 3**-10, 2**-10, 1**-10, 1**-5],
                     fp=[20, 17, 16, 15, 14, 7, 5])

    # Finally, return the zoom level and the associated boundary-box center coordinates
    return zoom, b_box.center
0

These solutions only kinda work, the problem is that the pixel size changes with the latitude. So if you want a general solution (and cannot talk to mapbox), I used opencv to find the max and min, lat and lon points, on a "test image", then calculate the pixel length in the y axis and the pixel length in the x axis, from max zoom (sometimes 22, or I skip to 20) to min zoom 0.

This is the sample "test image" generated with the max and min lat and long points in pink and orange:enter image description here

This is an image of the annotated map:enter image description here

    def get_marker_location(self, color_min, color_max, hsv):
        # cv2.imshow("hsv", hsv)
        # cv2.waitKey(0)
        mask = cv2.inRange(hsv, color_min, color_max)
        # cv2.imshow("Image", mask)
        # cv2.waitKey(0)
        if cv2.countNonZero(mask) == 0:
            return False, None, None
        cnts, hierarchies = cv2.findContours(mask, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)

        for i in cnts:
            M = cv2.moments(i)
            if M['m00'] != 0:
                cX = int(M["m10"] / M["m00"])
                cY = int(M["m01"] / M["m00"])

                return True, cX, cY


    def get_zoom(self, lons, lats, height, width):
        fig = go.Figure()

        # Get max min long lat per owner
        maxlon, minlon = np.amax(lons), np.amin(lons)
        maxlat, minlat = np.amax(lats), np.amin(lats)

        center = {
            'lon': round((maxlon + minlon) / 2, 6),
            'lat': round((maxlat + minlat) / 2, 6)
        }

        # Place each on map in different colors
        # Pink ff00ff hsv(300,100,100)
        pink_min = (147,219,208)
        pink_max = (153,255,255)
        fig.add_trace(go.Scattermapbox(lon=[minlon], lat=[minlat], 
                                        mode='markers', 
                                        marker=dict(color='#FF00FF')))
        # Oraange ff6000 hsv(23,100,100)
        orange_min = np.array([10,230,236])
        orange_max = np.array([12,255,255])
        fig.add_trace(go.Scattermapbox(lon=[maxlon], lat=[maxlat], 
                                        mode='markers', 
                                        marker=dict(color='#FF6000')))

        # Change start number for small area, skip if longer
        start_zoom = 20
        # extra_zoom_threshold = 0.00762 # 25ft in km
        extra_zoom_threshold = 0.01524 # 50ft in km
        max_min_dist = gpd.geodesic(gp.Point(minlat, minlon),gp.Point(maxlat, maxlon)).km
        print(f'max_min_dist: {max_min_dist}')
        print(f'extra_zoom_threshold: {extra_zoom_threshold}')
        if extra_zoom_threshold > max_min_dist:
            start_zoom = 22

        for i in range(start_zoom, -1, -1):
            # Make images
            fig.update_layout(template='plotly_white', 
                                showlegend=False, height=height, width=width, 
                                margin={'l': 0,'r': 0,'b': 0,'t': 0,},
                                mapbox={'style':'carto-positron', 
                                        'zoom':i,
                                        'center': {'lon': center['lon'], 'lat': center['lat']}})
            fig.write_image("check_zoom.png")

            # Check for colors
            img = cv2.imread('check_zoom.png')
            hsv = cv2.cvtColor(img, cv2.COLOR_BGR2HSV)
            pink_loc = dict()
            orange_loc = dict()
            # min
            pink_loc['in_image'], pink_loc['cX'], pink_loc['cY'] = self.get_marker_location(pink_min, pink_max, hsv)
            # max
            orange_loc['in_image'], orange_loc['cX'], orange_loc['cY'] = self.get_marker_location(orange_min, orange_max, hsv)
            # x = 1/0

            if (pink_loc['in_image'] and orange_loc['in_image']) or i == 0:
                # Compute Long and Lat pixel lengths
                # Calc lon lat distance / number of pixels
                pixel_len_lonx = gpd.geodesic(gp.Point(center['lat'], minlon),gp.Point(center['lat'], maxlon)).km / abs(orange_loc['cX'] - pink_loc['cX'])
                pixel_len_laty = gpd.geodesic(gp.Point(minlat, center['lon']),gp.Point(maxlat, center['lon'])).km / abs(orange_loc['cY'] - pink_loc['cY'])
                
                dy = (height/2)*pixel_len_laty # km
                dx = (width/2)*pixel_len_lonx # km
                
                max_lat = gpd.geodesic(kilometers=dy).destination(gp.Point(center['lat'], center['lon']), 0)[0]
                min_lat = gpd.geodesic(kilometers=dy).destination(gp.Point(center['lat'], center['lon']), 180)[0]
                max_lon = gpd.geodesic(kilometers=dx).destination(gp.Point(center['lat'], center['lon']), 90)[1]
                min_lon = gpd.geodesic(kilometers=dx).destination(gp.Point(center['lat'], center['lon']), 270)[1]

                return i, center, max_lat, min_lat, max_lon, min_lon

    def get_mapbox_site_map(self):
        # generate site map
        fig = go.Figure()

        height = 800
        width = 800
        annotation_counter = 0

        if len(self.lines_df):
            l_lat = np.concatenate(self.lines_df['lines'].apply(lambda g: [c[0] for c in g] + [None]).values)
            l_lon = np.concatenate(self.lines_df['lines'].apply(lambda g: [c[1] for c in g] + [None]).values)
        if len(self.gates_df):
            g_lat = np.concatenate(self.gates_df['gates'].apply(lambda g: [c[0] for c in g] + [None]).values)
            g_lon = np.concatenate(self.gates_df['gates'].apply(lambda g: [c[1] for c in g] + [None]).values)
            
        if len(self.gates_df) and len(self.lines_df):
            lg_lat = np.concatenate((l_lat, g_lat))
            lg_lon = np.concatenate((l_lon, g_lon))

            # Get zoom level => Get lat pixel distance, get long pixel distance => Annotate
            zoom, center, max_lat, min_lat, max_lon, min_lon = self.get_zoom(lg_lon[lg_lon != None], lg_lat[lg_lat != None], height, width)
        elif len(self.lines_df):
            # Get zoom level => Get lat pixel distance, get long pixel distance => Annotate
            zoom, center, max_lat, min_lat, max_lon, min_lon = self.get_zoom(l_lon[l_lon != None], l_lat[l_lat != None], height, width)
        elif len(self.gates_df):
            # Get zoom level => Get lat pixel distance, get long pixel distance => Annotate
            zoom, center, max_lat, min_lat, max_lon, min_lon = self.get_zoom(g_lon[g_lat != None], g_lat[g_lat != None], height, width)

        for index in self.lines_df.index:
            line = self.lines_df.at[index, 'lines']

            # 1 is lng x, 0 is lat y
            # x.append(line[0][1])
            # y.append(line[0][0])

            pt1 = line[0]
            pt2 = line[1]
            x_annotation = min(pt1[1], pt2[1]) + (abs(pt2[1] - pt1[1]) / 2)
            y_annotation = min(pt1[0], pt2[0]) + (abs(pt2[0] - pt1[0]) / 2)
            x_annotation = (x_annotation - min_lon)/(max_lon - min_lon)
            y_annotation = (y_annotation - min_lat)/(max_lat - min_lat)
            # print(f'zoom {zoom} x {x_annotation} y {y_annotation}')

            if 2 * (abs(pt2[1] - pt1[1]) / 2) <= (abs(pt2[0] - pt1[0]) / 2):
                xanchor = 'left'
            else:
                xanchor = 'center'

            str_i = str(index).replace('Line ', 'L')
            fig.add_annotation(x=x_annotation,
                                xanchor=xanchor,
                                y=y_annotation,
                                xref='paper',yref='paper',
                                yanchor='bottom',
                                text=f'<b>{str_i}: {str(self.lines_df.at[index, "distance"])}ft</b>',
                                font=dict(size=15, color="darkgreen"),
                                showarrow=False)

            annotation_counter += 1

        if len(self.lines_df):
            fig.add_trace(go.Scattermapbox(lon=l_lon, lat=l_lat, 
                                            mode='markers+lines', 
                                            marker=dict(color='#00B900'), 
                                            line=dict(color='#00B900')))

        annotation_counter = 0

        for index in self.gates_df.index:
            gate = self.gates_df.at[index, 'gates']

            # 1 is lng, 0 is lat
            # x.append(gate[0][1])
            # y.append(gate[0][0])

            pt1 = gate[0]
            pt2 = gate[1]
            x_annotation = min(pt1[1], pt2[1]) + (abs(pt2[1] - pt1[1]) / 2)
            y_annotation = min(pt1[0], pt2[0]) + (abs(pt2[0] - pt1[0]) / 2)
            x_annotation = (x_annotation - min_lon)/(max_lon - min_lon)
            y_annotation = (y_annotation - min_lat)/(max_lat - min_lat)

            if 2 * (abs(pt2[1] - pt1[1]) / 2) <= (abs(pt2[0] - pt1[0]) / 2):
                xanchor = 'left'
            else:
                xanchor = 'center'

            str_i = str(index).replace('Gate ', 'G')
            fig.add_annotation(x=x_annotation,
                                xanchor=xanchor,
                                y=y_annotation,
                                xref='paper',yref='paper',
                                yanchor='bottom',
                                text=f'<b>{str_i}: {str(self.gates_df.at[index, "distance"])}ft</b>',
                                font=dict(size=15, color="#361c00"),
                                showarrow=False)

            annotation_counter += 1

        if len(self.gates_df):
            fig.add_trace(go.Scattermapbox(lon=g_lon, lat=g_lat, 
                                            mode='markers+lines', 
                                            marker=dict(color='#8B4513'), 
                                            line=dict(color='#8B4513')))

        fig.update_yaxes(showticklabels=False)
        fig.update_layout(template='plotly_white', 
                            showlegend=False, height=height, width=width, 
                            margin={'l': 0,'r': 0,'b': 0,'t': 0,},
                            mapbox={'style':'carto-positron', 
                                    'zoom':zoom,
                                    'center': {'lon': center['lon'], 'lat': center['lat']}})

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.