This content requires the base game DCS World Steam Edition on Steam in order to play.

## About This Content
Note: This is the exact same simulation of the F-15C as featured in DCS:
Flaming Cliffs 3.

The F-15 has often been labeled as the greatest fighter aircraft in the world
from the 1970s until the early 21st century. Designed to counter the
exaggerated capabilities of the Soviet MiG-25 “Foxbat”, the F-15 has been the
backbone of U.S. air defense for three decades. The F-15C, equipped with
improved avionics and weapons over the original F-15A, has scored over 100
air-to-air victories in the service of Israel, Saudi Arabia, and the U.S.
without suffering any losses.

The F-15C rules the Beyond Visual Range arena (BVR). No slouch in a dogfight,
the F-15C excels at finding targets, positively identifying them as hostile,
and engaging them with AIM-120 AMRAAM missiles before the enemy can respond.

The F-15C’s versatile pulse-Doppler radar system can look up at high-flying
targets and down at low-flying targets without being confused by ground
clutter. It can detect and track aircraft and small high-speed targets at
distances beyond visual range down to close range, and at altitudes down to
tree-top level. The radar feeds target information into the central computer
for effective weapons delivery. For close-in dogfights, the radar
automatically acquires enemy aircraft, and this information is projected on
the head-up display.

F-15C for DCS World focuses on ease of use without complicated cockpit
interaction, significantly reducing the learning curve. As such, F-15C
features keyboard and joystick cockpit commands with a focus on the most
mission critical of cockpit systems.

Read more about the F-15C for DCS World here:

## Features:
* Detailed and accurate 3D model and animations
* Six Degrees of Freedom (6DOF) capable cockpit
* Professional Flight Model (PFM)
* Campaign and missions
* F-15C skins from a wide array of squadrons
* Both Simulation and Game modes

The F-15C for DCS World includes a Professional Flight Model (PFM). Highlights
of the PFM include:

Aircraft performance is constantly recalculated based on standard physics
equations describing the translational and rotational motion of a rigid body
under the influence of external forces and moments, regardless of the nature
of their origin.

• Trajectory and angular motion looks more natural due to the correct modeling
of the inertial properties of the aircraft.
• Unlike with Standard Flight Model (SFM) aircraft, the F-15C AFM does not
show noticeable transitions between modes, which appear as unnaturally sharp
attitude or position change. For example: when executing a tailslide, advanced
flight maneuvers, landing when not wings level, and touching down with a
single wheel.
• AFM naturally takes into account the gyroscopic effects on the plane’s
rotation (SFM does not model this at all).
• Asymmetric external forces (such as differential throttle), as well as
external forces not applied through the aircraft center of gravity (eg, engine
thrust and drag from asymmetric stores) are properly modeled throughout the
flight envelope, causing properly applied torque.
• Aircraft center of gravity can shift with AFM based on various in-flight
events.
• There is a concept of lateral and longitudinal center, which may shift
depending on fuel load and external stores.
• AFM naturally models asymmetrical external stores which properly influences
performance depending on airspeed, G load, and other factors.

The aerodynamic model of the AFM calculates aerodynamic characteristics of the
aircraft, considering it a set of interconnected airframe elements, such as
wings, fuselage, stabilators, etc. Each of these components has its
aerodynamics calculated separately based on local angles of attack, airspeeds,
mach numbers, and airflow, also considering pilot input as well as each
component’s damage state.

• Aircraft aerodynamics are fully modeled for the entire flight envelope.
• Lateral and longitudinal control effects as well as balance along each axis
vary based on angle of attack and lateral and longitudinal static stability.
• Wing autorotation is naturally taken into account when rolling at high
angles of attack.
• Kinematic, aerodynamic and inertial effects of each of the three axes of
static stability is naturally calculated, such as in sideslip when rolling, or
rolling during rudder movement, etc.
• Sideslip angle is not just based on pilot input, as is the case with SFM,
but also considers aircraft attitude.
• For aircraft damage, changes in performance are not hard-coded but are
calculated dynamically by fully or partially excluding affected components
from physics calculations.
• The aircraft stall is properly modeled, creating realistic wing rocking and
wandering aircraft nose behavior.
Dynamic jet engine modeling considers a complex set of parameters including
the air intake, compressor, combustor, turbine, and the afterburner nozzles.
• Engine RPM depends on altitude and Mach number, as well as atmospheric
conditions such as temperature and air pressure.
• Brief engine overspeed is modeled in throttle response.
• Engine overspeed and throttling response, as well as general throttle
control (response speed) vary based on current RPM.
• Turbine exhaust temperature is modeled in intricate detail, considering
multiple parameters such as engine RPM, flight parameters, and atmospheric
conditions.
• Fuel consumption is calculated realistically based on both engine RPM and
flight parameters.
• Engine operating parameters, such as RPM and exhaust temperature, are
accurately modeled during the entire startup and shutdown process. F-15’s AFM
properly models such events turbine windmill in a disabled engine, engine
relighting, and automatic air start.

F-15C for DCS World