Add gallery example for cross-axis slope backtracking

docs/examples/plot_single_axis_tracking_on_sloped_terrain.py

@@ -0,0 +1,177 @@
+"""
+Backtracking on sloped terrain
+==============================
+
+Modeling backtracking for single-axis tracker arrays on sloped terrain.
+"""
+
+# %%
+# Tracker systems use backtracking to avoid row-to-row shading when the
+# sun is low in the sky. The backtracking strategy orients the modules exactly
+# on the boundary between shaded and unshaded so that the modules are oriented
+# as much towards the sun as possible while still remaining unshaded.
+# Unlike the true-tracking calculation (which only depends on solar position),
+# calculating the backtracking angle requires knowledge of the relative spacing
+# of adjacent tracker rows. This example shows how the backtracking angle
+# changes based on a vertical offset between rows caused by sloped terrain.
+# It uses :py:func:`pvlib.tracking.calc_axis_tilt` and
+# :py:func:`pvlib.tracking.calc_cross_axis_tilt` to calculate the necessary
+# array geometry parameters and :py:func:`pvlib.tracking.singleaxis` to
+# calculate the backtracking angles.
+#
+# Angle conventions
+# -----------------
+#
+# First let's go over the sign conventions used for angles. In contrast to
+# fixed-tilt arrays where the azimuth is that of the normal to the panels, the
+# convention for the azimuth of a single-axis tracker is along the tracker
+# axis. Note that the axis azimuth is a property of the array and is distinct
+# from the azimuth of the panel orientation, which changes based on tracker
+# rotation angle. Because the tracker axis points in two directions, there are
+# two choices for the axis azimuth angle, and by convention (at least in the
+# northern hemisphere), the more southward angle is chosen:
+#
+# .. image:: ../_images/tracker_azimuth_angle_convention.png
+#   :alt: Image showing the azimuth convention for single-axis tracker arrays.
+#   :width: 500
+#   :align: center
+#
+# Note that, as with fixed-tilt arrays, the axis azimuth is determined as the
+# angle clockwise from north. The azimuth of the terrain's slope is also
+# determined as an angle clockwise from north, pointing in the direction
+# of falling slope. So for example, a hillside that slopes down to the east
+# has an azimuth of 90 degrees.
+#
+# Using the axis azimuth convention above, the sign convention for tracker
+# rotations is given by the
+# `right-hand rule <https://en.wikipedia.org/wiki/Right-hand_rule>`_.
+# Point the right hand thumb along the axis in the direction of the axis
+# azimuth and the fingers curl in the direction of positive rotation angle:
+#
+# .. image:: ../_images/tracker_rotation_angle_convention.png
+#   :alt: Image showing the rotation sign convention for single-axis trackers.
+#   :width: 500
+#   :align: center
+#
+# So for an array with ``axis_azimuth=180`` (tracker axis aligned perfectly
+# north-south), pointing the right-hand thumb along the axis azimuth has the
+# fingers curling towards the west, meaning rotations towards the west are
+# positive and rotations towards the east are negative.
+#
+# The ground slope itself is always positive, but the component of the slope
+# perpendicular to the tracker axes can be positive or negative. The convention
+# for the cross-axis slope angle follows the right-hand rule: align
+# the right-hand thumb along the tracker axis in the direction of the axis
+# azimuth and the fingers curl towards positive angles. So in this example,
+# with the axis azimuth coming out of the page, an east-facing, downward slope
+# is a negative rotation from horizontal:
+#
+# .. image:: ../_images/ground_slope_angle_convention.png
+#   :alt: Image showing the ground slope sign convention.
+#   :width: 500
+#   :align: center
+#
+
+# %%
+# Rotation curves
+# ---------------
+#
+# Now, let's plot the simple case where the tracker axes are at right angles
+# to the direction of the slope.  In this case, the cross-axis tilt angle
+# is the same as the slope of the terrain and the tracker axis itself is
+# horizontal.
+
+from pvlib import solarposition, tracking
+import pandas as pd
+import matplotlib.pyplot as plt
+
+# PV system parameters
+tz = 'US/Eastern'
+lat, lon = 40, -80
+gcr = 0.4
+
+# calculate the solar position
+times = pd.date_range('2019-01-01 06:00', '2019-01-01 18:00', closed='left',
+                      freq='1min', tz=tz)
+solpos = solarposition.get_solarposition(times, lat, lon)
+
+# compare the backtracking angle at various terrain slopes
+fig, ax = plt.subplots()
+for cross_axis_tilt in [0, 5, 10]:
+    tracker_data = tracking.singleaxis(
+        apparent_zenith=solpos['apparent_zenith'],
+        apparent_azimuth=solpos['azimuth'],
+        axis_tilt=0,  # flat because the axis is perpendicular to the slope
+        axis_azimuth=180,  # N-S axis, azimuth facing south
+        max_angle=90,
+        backtrack=True,
+        gcr=gcr,
+        cross_axis_tilt=cross_axis_tilt)
+
+    # tracker rotation is undefined at night
+    backtracking_position = tracker_data['tracker_theta'].fillna(0)
+    label = 'cross-axis tilt: {}°'.format(cross_axis_tilt)
+    backtracking_position.plot(label=label, ax=ax)
+
+plt.legend()
+plt.title('Backtracking Curves')
+plt.show()
+
+# %%
+# This plot shows how backtracking changes based on the slope between rows.
+# For example, unlike the flat-terrain backtracking curve, the sloped-terrain
+# curves do not approach zero at the end of the day. Because of the vertical
+# offset between rows introduced by the sloped terrain, the trackers can be
+# slightly tilted without shading each other.
+#
+# Now let's examine the general case where the terrain slope makes an
+# inconvenient angle to the tracker axes. For example, consider an array
+# with north-south axes on terrain that slopes down to the south-south-east.
+# Assuming the axes are installed parallel to the ground, the northern ends
+# of the axes will be higher than the southern ends. But because the slope
+# isn't purely parallel or perpendicular to the axes, the axis tilt and
+# cross-axis tilt angles are not immediately obvious. We can use pvlib
+# to calculate them for us:
+
+# terrain slopes 10 degrees downward to the south-south-east. note: because
+# slope_azimuth is defined in the direction of falling slope, slope_tilt is
+# always positive.
+slope_azimuth = 155
+slope_tilt = 10
+axis_azimuth = 180  # tracker axis is still N-S
+
+# calculate the tracker axis tilt, assuming that the axis follows the terrain:
+axis_tilt = tracking.calc_axis_tilt(slope_azimuth, slope_tilt, axis_azimuth)
+
+# calculate the cross-axis tilt:
+cross_axis_tilt = tracking.calc_cross_axis_tilt(slope_azimuth, slope_tilt,
+                                                axis_azimuth, axis_tilt)
+
+print('Axis tilt:', '{:0.01f}°'.format(axis_tilt))
+print('Cross-axis tilt:', '{:0.01f}°'.format(cross_axis_tilt))
+
+# %%
+# And now we can pass use these values to generate the tracker curve as
+# before:
+
+tracker_data = tracking.singleaxis(
+    apparent_zenith=solpos['apparent_zenith'],
+    apparent_azimuth=solpos['azimuth'],
+    axis_tilt=axis_tilt,  # no longer flat because the terrain imparts a tilt
+    axis_azimuth=axis_azimuth,
+    max_angle=90,
+    backtrack=True,
+    gcr=gcr,
+    cross_axis_tilt=cross_axis_tilt)
+
+backtracking_position = tracker_data['tracker_theta'].fillna(0)
+backtracking_position.plot()
+
+title_template = 'Axis tilt: {:0.01f}°   Cross-axis tilt: {:0.01f}°'
+plt.title(title_template.format(axis_tilt, cross_axis_tilt))
+plt.show()
+
+# %%
+# Note that the backtracking curve is roughly mirrored compared with the
+# earlier example -- it is because the terrain is now sloped somewhat to the
+# east instead of west.

docs/sphinx/source/whatsnew/v0.8.1.rst

@@ -26,7 +26,7 @@ Testing
 
 Documentation
 ~~~~~~~~~~~~~
-
+* Add gallery example about backtracking on sloped terrain. (:pull:`1077`)
 
 Requirements
 ~~~~~~~~~~~~