diff options
author | Michael Krupa <kroopson@wp.pl> | 2011-12-08 19:29:38 +0400 |
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committer | Michael Krupa <kroopson@wp.pl> | 2011-12-08 19:29:38 +0400 |
commit | 3f139678404e0f76d2fae817d12e8c937d4f57eb (patch) | |
tree | bda96efea0e1ea7b49edb8331598355ecdebc507 /io_anim_nuke_chan | |
parent | 21eaa36c71f3714404b4a53a5f668662790154f3 (diff) |
Updated to use bpy.types.Camera.angle_y property.
Diffstat (limited to 'io_anim_nuke_chan')
-rw-r--r-- | io_anim_nuke_chan/export_nuke_chan.py | 11 | ||||
-rw-r--r-- | io_anim_nuke_chan/import_nuke_chan.py | 5 |
2 files changed, 4 insertions, 12 deletions
diff --git a/io_anim_nuke_chan/export_nuke_chan.py b/io_anim_nuke_chan/export_nuke_chan.py index e0fdefb5..bdb8a87c 100644 --- a/io_anim_nuke_chan/export_nuke_chan.py +++ b/io_anim_nuke_chan/export_nuke_chan.py @@ -23,7 +23,7 @@ It takes the currently active object and writes it's transformation data into a text file with .chan extension.""" from mathutils import Matrix -from math import radians, degrees, atan2 +from math import radians, degrees def save_chan(context, filepath, y_up, rot_ord): @@ -73,14 +73,7 @@ def save_chan(context, filepath, y_up, rot_ord): if camera: sensor_x = camera.sensor_width sensor_y = camera.sensor_height - cam_lens = camera.lens - - # calculate the vertical field of view - # we know the vertical size of (virtual) sensor, the focal length - # of the camera so all we need to do is to feed this data to - # atan2 function whitch returns the degree (in radians) of - # an angle formed by a triangle with two legs of a given lengths - vfov = degrees(atan2(sensor_y / 2, cam_lens)) * 2.0 + vfov = degrees(camera.angle_y) fw("%f" % vfov) fw("\n") diff --git a/io_anim_nuke_chan/import_nuke_chan.py b/io_anim_nuke_chan/import_nuke_chan.py index 05bbfa0c..48103e09 100644 --- a/io_anim_nuke_chan/import_nuke_chan.py +++ b/io_anim_nuke_chan/import_nuke_chan.py @@ -21,7 +21,7 @@ """ This script is an importer for the nuke's .chan files""" from mathutils import Vector, Matrix, Euler -from math import radians, tan +from math import radians def read_chan(context, filepath, z_up, rot_ord, sensor_width, sensor_height): @@ -103,11 +103,10 @@ def read_chan(context, filepath, z_up, rot_ord, sensor_width, sensor_height): # check if the object is camera and fov data is present if camera and len(data) > 7: - v_fov = float(data[7]) camera.sensor_fit = 'HORIZONTAL' camera.sensor_width = sensor_width camera.sensor_height = sensor_height - camera.lens = (sensor_height / 2.0) / tan(radians(v_fov / 2.0)) + camera.angle_y = radiansfloat(data[7]) camera.keyframe_insert("lens") filehandle.close() |