Source code for RCAIDE.Library.Mission.Segments.Climb.Constant_Speed_Constant_Angle
# RCAIDE/Library/Missions/Segments/Climb/Constant_Speed_Constant_Angle.py
#
#
# Created: Jul 2023, M. Clarke
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# IMPORT
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# Package imports
import numpy as np
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# Initialize Conditions
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[docs]
def initialize_conditions(segment):
"""
Initializes conditions for constant speed and angle climb segment
Parameters
----------
segment : Segment
The mission segment being analyzed
Notes
-----
This function sets up the initial conditions for a climb segment with constant
true airspeed and constant climb angle.
**Required Segment Components**
segment:
- climb_angle : float
Fixed climb angle [rad]
- air_speed : float
True airspeed to maintain [m/s]
- altitude_start : float
Initial altitude [m]
- altitude_end : float
Final altitude [m]
- sideslip_angle : float
Aircraft sideslip angle [rad]
- state:
numerics.dimensionless.control_points : array
Discretization points [-]
conditions : Data
State conditions container
**Calculation Process**
1. Discretize altitude profile
2. Decompose constant velocity into components using:
- Fixed climb angle
- Sideslip angle
- Constant speed requirement
**Major Assumptions**
* Constant true airspeed
* Fixed climb angle
* Small angle approximations
* Quasi-steady flight
Returns
-------
None
Updates segment conditions directly:
- conditions.frames.inertial.velocity_vector [m/s]
- conditions.frames.inertial.position_vector [m]
- conditions.freestream.altitude [m]
See Also
--------
RCAIDE.Framework.Mission.Segments
"""
# unpack
climb_angle = segment.climb_angle
air_speed = segment.air_speed
alt0 = segment.altitude_start
altf = segment.altitude_end
beta = segment.sideslip_angle
t_nondim = segment.state.numerics.dimensionless.control_points
conditions = segment.state.conditions
# check for initial velocity
if air_speed is None:
if not segment.state.initials: raise AttributeError('airspeed not set')
air_speed = np.linalg.norm(segment.state.initials.conditions.frames.inertial.velocity_vector[-1])
# check for initial altitude
if alt0 is None:
if not segment.state.initials: raise AttributeError('initial altitude not set')
alt0 = -1.0 * segment.state.initials.conditions.frames.inertial.position_vector[-1,2]
# discretize on altitude
alt = t_nondim * (altf-alt0) + alt0
# process velocity vector
v_mag = air_speed
v_x = np.cos(beta)*v_mag * np.cos(climb_angle)
v_y = np.sin(beta)*v_mag * np.cos(climb_angle)
v_z = -v_mag * np.sin(climb_angle)
# pack conditions
conditions.frames.inertial.velocity_vector[:,0] = v_x
conditions.frames.inertial.velocity_vector[:,1] = v_y
conditions.frames.inertial.velocity_vector[:,2] = v_z
conditions.frames.inertial.position_vector[:,2] = -alt[:,0] # z points down
conditions.freestream.altitude[:,0] = alt[:,0] # positive altitude in this context
