Instrument Rating Flight Training Oklahoma
The instrument rating (IFR) is something that will eventually come along if you've been flying very long. Typically, it comes up when looking at buying an aircraft or seeking a commercial pilot career, but otherwise, some pilots may take quite a while to get their instrument rating in Oklahoma. Though many pilots in Oklahoma do eventually get an instrument rating, chances are learning to fly IFR in Oklahoma now could greatly benefit your future flying.
An instrument rating will make you a better pilot, is required to get a commercial pilot certificate, and will generally lower your insurance rates. Flying on instruments in Oklahoma will make you a better pilot. When it comes to flying on instruments, precision is the keyword. There are many different things to learn for your instrument rating, but none are more difficult and rewarding as learning to fly with precision.
Once you complete your instrument rating in Oklahoma, you will be able to not only hit a specific altitude or descent rate but hold it. You will be more in control of your aircraft than you ever thought possible and this will surely affect your flying in general.
Perhaps you're not thinking about it right this moment, but at some point in the future, you may decide to get a commercial pilot certificate. That doesn't mean you have to run off to the airlines. There are many commercial pilots that never really get paid to fly, but it is nice to have the option.
Commercial Pilots in Oklahoma Need an Instrument Rating to Get a Job
Maybe your company has a nice aircraft that you'd like to spend some time in or you'd occasionally like to take on a paying passenger--whatever the case, although it's not required, you're going to want an instrument rating to go along with your commercial pilot certificate.
If you wait until then to get instrument rated, you're going to have a lot of training to do. Instead, reap the benefits of learning precise flying early and you can sail through commercial pilot training when you need it.
Do You Want to Earn Your Instrument Rating IFR in Oklahoma?
Insurance rates are generally cheaper for instrument-rated pilots. Perhaps the poorest-kept secret of the aviation insurance industry is that instrument-rated pilots enjoy rates that are generally cheaper. The increased training instrument-rated pilots take on and their increased skill pay off in lower insurance premiums. Depending on the type of aircraft you fly, this can be a very significant amount of money.
So, if you'd like to be a better pilot with lower insurance rates and you might get a commercial pilot certificate, you should definitely consider an instrument rating. Sure it may be difficult, but the sense of accomplishment and precision flying skill is more than worth it in the long run.
Legend has it that the instrument rating in Oklahoma is the most difficult to earn of all licenses, ratings, and endorsements. And if you talk to an instrument-rated pilot, he or she will probably agree. However, the instrument rating could also be the most rewarding of all to earn, and the benefits and privileges of acquiring the rating are well worth the initial effort.
Simply stated, the instrument rating allows pilots to fly under instrument flight rules (IFR) in Oklahoma, in instrument meteorological conditions (IMC), and in class A airspace (the airspace between 18,000 feet msl and 60,000 feet msl). IMC is loosely defined as conditions that do not meet the basic requirements of operating under visual flight rules (VFR), including ceilings less than 1000 feet above airport elevation and/or visibility less than 3 miles at the airport.
Although the instrument rating gives pilots permission to operate in less than basic VFR conditions, it's not a "license" to fly in bad weather. Prudent pilots do not launch into deadly weather just because they are instrument rated. Learn about instrument rating training.
FAA - A History of Airplane Structures Facts for Oklahoma
There are five major stresses to which all aircraft are subjected: Bending. Bending stress is a combination of compression and tension. The rod in Figure 1-14E has been shortened (compressed) on the inside of the bend and stretched on the outside of the bend. A single member of the structure may be subjected to a combination of stresses. In most cases, the structural members are designed to carry end loads rather than side loads. They are designed to be subjected to tension or compression rather than bending.
Aviation Facts - High-Speed Aerodynamics
Listed below are a range of conditions that are encountered by aircraft as their designed speed increases. Subsonic conditions occur for Mach numbers less than one (100–350 mph). For the lowest subsonic conditions, compressibility can be ignored. As the speed of the object approaches the speed of sound, the flight Mach number is nearly equal to one, M = 1 (350–760 mph), and the flow is said to be transonic. At some locations on the object, the local speed of air exceeds the speed of sound. Compressibility effects are most important in transonic flows and lead to the early belief in a sound barrier. Flight faster than sound was thought to be impossible. In fact, the sound barrier was only an increase in the drag near sonic conditions because of compressibility effects. Because of the high drag associated with compressibility effects, aircraft are not operated in cruise conditions near Mach 1. Supersonic conditions occur for numbers greater than Mach 1, but less than Mach 3 (760–2,280mph). Compressibility effects of gas are important in the design of supersonic aircraft because of the shockwaves that are generated by the surface of the object. For high supersonic speeds, between Mach 3 and Mach 5 (2,280–3,600 mph), aerodynamic heating becomes a very important factor in aircraft design. For speeds greater than Mach 5, the flow is said to be hypersonic. At these speeds, some of the energy of the object now goes into exciting the chemical bonds which hold together the nitrogen and oxygen molecules of the air. At hypersonic speeds, the chemistry of the air must be considered when determining forces on the object. When the space shuttle re-enters the atmosphere at high hypersonic speeds, close to Mach 25, the heated air becomes an ionized plasma of gas, and the spacecraft must be insulated ted from the extremely high temperatures.