Example #1
0
    def interpolate(self, time):
        """."""
        # Handle boundary conditions for matrix interpolation
        if (not self.actually_animated or time <= self.start_time):
            return Transform.from_transform(self.start_transform)
        if (time >= self.endTime):
            return self.end_transform

        dt = (time - self.start_time) / (self.end_ime - self.start_time)
        # Interpolate translation at _dt_
        trans = (1.0 - dt) * self.t_0 + dt * self.t_1

        # Interpolate rotation at _dt_
        rotate = slerp(dt, self.r_0, self.r_1)

        # Interpolate scale at _dt_
        scale = Matrix4x4()
        for i in range(3):
            for j in range(3):
                scale.m[i][j] = lerp(dt, self.s_o.m[i][j], self.s_1.m[i][j])

        # Compute interpolated matrix as product of interpolated components
        return translate(trans) * \
               rotate.to_transform() * \
               Transform(scale)
Example #2
0
    def interpolate(self, time):
        """."""
        # Handle boundary conditions for matrix interpolation
        if (not self.actually_animated or time <= self.start_time):
            return Transform.from_transform(self.start_transform)
        if (time >= self.endTime):
            return self.end_transform

        dt = (time - self.start_time) / (self.end_ime - self.start_time)
        # Interpolate translation at _dt_
        trans = (1.0 - dt) * self.t_0 + dt * self.t_1

        # Interpolate rotation at _dt_
        rotate = slerp(dt, self.r_0, self.r_1)

        # Interpolate scale at _dt_
        scale = Matrix4x4()
        for i in range(3):
            for j in range(3):
                scale.m[i][j] = lerp(dt, self.s_o.m[i][j], self.s_1.m[i][j])

        # Compute interpolated matrix as product of interpolated components
        return translate(trans) * \
               rotate.to_transform() * \
               Transform(scale)
Example #3
0
 def test_slerp(self):
     transform1 = rotate_z(30.0)
     q1 = Quaternion.from_transform(transform1)
     transform2 = rotate_z(90.0)
     q2 = Quaternion.from_transform(transform2)
     q_interp = slerp(0.5, q1, q2)
     transform3 = rotate_z(60)
     q3 = Quaternion.from_transform(transform3)
     self.assertEqual(q_interp, q3)
     self.assertEqual(q_interp.to_transform(), transform3)