FAR/AIM 2009: Federal Aviation Regulations/Aeronautical Information Manual (FAR/AIM series)

FAR/AIM 2009: Federal Aviation Regulations/Aeronautical Information Manual (FAR/AIM series) By Federal Aviation Administration List Price: $16.95 Price: $9.16 & eligible for FREE Super Saver Shipping on orders over $25. Details Availability: Usually ships in 1 to 3 months Ships from and sold by Amazon.com 15 new or used available from $9.16 Average customer review:

Product Description

Adhering to a reputation for excellence, this definitive manual of the latest civil aviation directives has been fully updated and indexed to clearly reflect all the changes in the Federal Aviation Regulations (FAR) and the Aeronautical Information Manual (AIM) over the past year. In addition to the regulations, AIM procedures, and redrawn AIM illustrations, this retypeset edition also includes a study guide for specific pilot certifications and ratings, a pilot/controller glossary, the NASA Aviation Safety reporting form, important FAA contact information, and a free e-mail service that accounts for regulation changes throughout the publication year. Updates are provided to account for FAA regulation changes throughout the publication year via the Aviation Supplies & Academics website.

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Product Details

• Amazon Sales Rank: #23037 in Books
• Published on: 2008-10-01
• Original language: English
• Number of items: 1
• Binding: Paperback
• 948 pages

Features

• ISBN13: 9781560277002
• BUY WITH CONFIDENCE, Over one million books sold! 98% Positive feedback. Compare our books, prices and service to the competition. 100% Satisfaction Guaranteed
• Brand New from Publisher. No Remainder Mark.

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Editorial Reviews

About the Author

The Federal Aviation Administration is the government organization that sets and regulates procedural standards for the aviation industry.

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Customer Reviews

Same format.
Every year I buy a FAR/AIM and I stick with ASA every time for two reasons:
*Very good index
*Good/easy font to read
It makes things easy to find....

Better
Last year I had the Jepp FAR/AIM and it was good, but this seems more precise in the formatting, and it's thinner. It also has the numbers on the flipping edge to know exactly what part you're in--much nicer. Best price ever!

You get what you get
This book provides the basics for most pilots. It is what you probably need. However, realize there are chapters from the FAR that you'll have to find elsewhere, like the FAA website. Overall, decent price for the book compared to buying it at the FBO or flight school.

Flight Timer 2 - Digital Aviation Flight Timer

Flight Timer 2 - Digital Aviation Flight Timer From Aviation Supplies and Academics Price: This item is not available for purchase from this store. Click here to go to Amazon to see other purchasing options. 1 new or used available from $39.99

Product Description

Designed by pilots for pilots, the ASA Flight Timer is a one of a kind chronometer that fills a gap in the instruction and pilot aid category. Ergonomically designed and engineered for reliability, ease and convenience, the ASA Flight Timer should be considered essential equipment for all aviators. The ASA Flight Timer has been created with pilot functionality in mind, featuring: * Large, easily readable LCD backlight display * Multi-function clock (AM/PM, Universal Coordinated Zulu time, and military time options); reset function prevent accidental resets * Three simultaneous timer options * Exclusive digital notepad for squawk codes or frequencies * Approach timer allows pilots to store up to 12 different approach times * Audible and visual alarm modes * Fuel timer * Stopwatch with 1/10th and 1/100th second digits * Intuitive push and rotate dial for quickly and easily setting times * Multiple mounting options Pilots will be able to accurately calculate time to the next waypoint, fuel tank changes, turns in holding or an instrument approach with complete confidence. The Flight Timer has been designed to meet the needs of all aviators, from student pilots working on their first cross-country to flight instructors and seasoned veterans. Applicable to both VFR and IFR flights, an ASA Flight Timer should be in every pilots flight bag.

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Product Details

• Amazon Sales Rank: #8778 in Office Product
• Brand: ASA
• Model: TIMER-2
• Dimensions: 1.50 pounds

Features

• Created with pilot functionality in mind
• Large, easily readable LCD backlight display
• Multi-function clock (AM/PM, 24 hour, UTC/Zulu)
• Digital notepad for squawk codes or frequencies
• Approach timer allows pilots to store up to 12 different approach times

Pathfinder Electronic Flight Computer (CX-2)

Pathfinder Electronic Flight Computer (CX-2) From Aviation Supplies and Academics Price: $147.99 Availability: Usually ships in 1-3 weeks Ships from and sold by Action Packaged, Inc. 4 new or used available from $60.00 Average customer review:

Product Description

Aviators can calculate true airspeed, ground speed, Mach number, altitudes, fuel, headings and courses, time/speed/distance, winds, and weight and balance. Includes 4 AAA batteries. ASAs electronic flight computer takes advantage of advances in display and microcomputer technologies for better performance and price. A menu of 34 functions gives users access to 40 aviation calculations, including weight and balance, with these features: -May be used for FAA and Canadian Exams --Users may bring the CX-2 with them to the testing centers for all pilot, mechanic, dispatcher, and FAA exams. -Numerous Aviation Functions --Calculate true airspeed, ground speed, mach number, altitudes, fuel, headings and courses, time/speed/distance, winds, headwind/crosswind components, gliding information, and weight and balance. -Ergonomic Design --The CX-2 features a simple keyboard and slim design. The hard-plastic carrying case protects the computer inside the flight bag, and fits on the back of the unit for storage while the computer is in use. -Interactive Functions --Functions can be used together in chain calculations, where the answer to a preceding problem is automatically entered into subsequent problems. Standard mathematical calculations and conversions can be performed within each aviation function. The CX-2 uses four AAA batteries (included).

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Product Details

• Amazon Sales Rank: #4684 in Single Detail Page Misc
• Brand: ASA
• Model: CX-2 Pathfinder
• Dimensions: 2.00 pounds

Features

• Numerous Aviation Functions
• User Friendly
• Ergonomic Design
• May Be Used for FAA and Canadian Exams
• 5-Year Warranty

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Customer Reviews

Review for CX-2 Flight Computer
This has proved to be an excellent product. It arrived on time. I would recommend this to student pilots.

Is a Private Pilot Considered an Amateur Pilot?

Is a Private Pilot Considered an Amateur Pilot? By Chet Val

The media is always on hand when an accident or incident involving a general aviation aircraft occurs. It seems that they watch like a hawk for anything negative news to promote. Be it for tv ratings, newspaper circulation, magazine sales, etc the watchful eye of the media has always been quick to carefully detail airplane crashes and near misses. The private pilot is always being scrutinized in the media and in many cases being referred to as an amateur pilot. The word amateur is defined in numerous ways. It can be defined as a person attached to a particular pursuit or study without formal training or pay. Another definition is someone who pursues a study or sport as an informal pastime or hobby. The definitions are similar and broad. The problem is that the term amateur pilot paints the picture of an individual who reads a magazine on flying airplanes, and then hops into the nearest cockpit and flies away. Acquiring a private pilot certificate and the legal means to fly an airplane indeed requires formal training as well as certain medical requirements as well as successful completion of numerous tests. So where does the word amateur come into the picture? In comparison, a private pilot flying for hobby and fun does in fact need substantially less training then a commercial pilot flying cargo or human beings across the sky professionally.

Flying for sport or hobby requires a private pilot certificate in the USA. There are also certificates available that require less training such as the Sport Pilot certificate. This certification carries with it certain stipulations due to the fact that it requires less training and is less costly to the student. The private certificate however provides the pilot with the ability to fly in controlled airspace which can be critical depending on where he or she lives or flies. Another difference between these two certificates is the need for a medical exam by a certified medical examiner specifically qualified and approved by the FAA. A Sport pilot certificate does not require the student to pass an aviation medical exam.

Future pilots must be able to understand, speak, and read English. Aircraft control towers and airports, use the English language for communication. This is actually true in most airports around the world, even where English is not the native language. Choosing a flight school is very important. Information is always available at your local general aviation airports. Training does not come cheap. A private pilot certificate requires forty hours minimum of actual flying time. This includes the time in the airplane with an instructor as well as time spent flying solo. Many flight schools recommend students seek a medical certificate from your local FAA certified physician prior to starting any training. Once the student has passed that, your flight school or private flight instructor will begin the process of both ground training as well as in-flight training. Ground school varies tremendously among students based on amount of time spent per week along with the rate of material absorption. Student pilots can acquire information through a variety of methods including the internet, training videos, and good old fashion books and manuals. At some point in your training beyond basic ground school, student pilots have to take a multiple choice written test, nowadays typically from a computer terminal, with software provided by the Federal Aviation Administration.

Upon passing the written FAA test, as it is referred to, you need to log in-flight training hours beyond the minimums required by the FAA. For a private certificate, students need to log solo time, night flying time, and demonstrate the ability to successfully compete cross-country flights which are flights from one airport to another. A check-ride, or final test, is then required with your local FAA designated examiner. The check-ride includes an oral test accompanied by a practical test where the student must demonstrate a variety of specific maneuvers and familiarity with the airplane. This is the point where the word amateur becomes skewed. With all the requirements met and tests passed, the student will be issued a private pilot certificate. Although a pilot's experience is measured over time in flying hours and new pilots certainly lack air time when compared to a pilot who has been flying for years or even decades, it still seems a bit harsh to label a private pilot as an amateur pilot.

Chet owns and operates Eye of the Pilot, a private pilot networking site dedicated to sharing the experience of general aviation and the adventure of being a private pilot. You can visit Eye of the Pilot to view general aviation pilot videos and aviation pictures submitted by members. Account signup is free for pilots of any rating.

Article Source: http://EzineArticles.com/?expert=Chet_Val

Pratt and Whitney - A History

Pratt and Whitney - A History By John B Beck John B Beck Level: Basic 49 years old. Married. 4 sons and 1 stepdaughter. I have a passion for anything to do with aviation. I love books also. I want ... ...

Pratt and Whitney Aircraft manufactures aircraft engines. On their famous logo with the Eagle it says: "Dependable Engines". In later years the company had the following slogan: "The Eagle means Business". They have been manufacturing engines (piston and jet) since 1925. The man who started it was Frederick Brant Rentschler. And you thought the company was started by two people named Pratt and Whitney!

Well the Pratt & Whitney Aircraft story is a fairly long and convoluted one. Rentschler founded Wright Aeronautical. Wright Aeronautical was previously Wright-Martin. Wright-Martin was a merger of the Glenn L. Martin Company and the Wright Company which occurred in 1916. Wright Company was created by Orville and Wilbur Wright. Glenn Martin resigned from Wright-Martin in 1917. The company was renamed Wright Aeronautical in 1919. The Wright "Whirlwind" engine was used on the plane that the famed aviator Charles Lindbergh flew solo nonstop across the Atlantic Ocean on May 21, 1927. Then in 1924 Rentschler left Wright Aeronautical with some engineers after a dispute regarding funding for an air-cooled engine which the government requested development of. So Rentschler headed to Connecticut to Pratt & Whitney which at the time was called the "Pratt & Whitney Machine Tool Company". It was founded in 1860 by Francis A. Pratt and Amos Whitney (a cousin of Eli Whitney). They were located in Hartford, Connecticut. Pratt & Whitney provided funds, building facilities, and even their name. Pratt & Whitney Aircraft was incorporated in 1925.

The following is but a short list of well-known aircraft that have had Pratt & Whitney engines installed on them:

B-52 Stratofortress (1952) - the J57
Boeing 707 (1958) - the JT3
SR-71 Blackbird (1964) - the J58
Boeing 747 (1966) - the JT9D
F-15 Eagle (1970) - the F100
Boeing 727 (1980) - the JT8D
Boeing 747 (1987) - the PW4000
Boeing 777 (1989) - the PW4084
F/A-22 Raptor (1991) - the F119

Pratt & Whitney Aircraft manufactured 363,610 piston aircraft engines during World War II which was nearly half of all the engines produced.

Charles Lindbergh was once employed at Pratt & Whitney Aircraft The desk he used can be seen at the Pratt & Whitney Museum in Hartford, CT. Connecticut's economy relies in large part on the Defense Industry and Pratt & Whitney Aircraft is the states largest private employer.

Over the years Pratt & Whitney Aircraft has made engines that have been installed in a large variety of civil and military aircraft. They have also made engines (both piston and jet) that have been used to generate electrical power on the ground. There power plants have been installed in U.S. Navy ships. They even in had small helicopter turbine engines installed on Indy and Formula One racing cars. Pratt & Whitney Aircraft also has a division in Canada that was founded in 1928. It makes turboprop engines for small aircraft.

In 1929 Rentschler incorporated the company called: "United Aircraft and Transport Company". The creation of United Airlines came about from this company. United Aircraft and Transport Company then became United Aircraft Corporation which was comprised of the following four companies: Pratt & Whitney, Vought Aircraft (from Chance Vought - another aviation legend - but this company left in 1954), Sikorsky Aircraft (from famed helicopter inventor Igor Sikorsky), and Hamilton-Standard which makes propellers. Then in 1975 United Aircraft Corporation became the United Technologies Corporation which we know today. United Technologies Corporation or UTC also has Carrier (air conditioning and refrigeration) and Otis (elevators) as business units.

The Marriage Between the Amateur Pilots and Stalled Airplanes

The Marriage Between the Amateur Pilots and Stalled Airplanes By Chet Val

Amateur pilots deliberately stalling an aircraft? Yes, it's a common occurrence and an essential aspect of every pilot's training. The stall can be mild and the stall can be fairly dramatic depending on the student pilot who is just learning stall recovery. People with limited knowledge of aircraft or possibly no familiarity with aviation at all, sometimes misinterpret the term stalled airplane to mean that the engine has stalled. A stall in relation to aviation and aircraft is defined as a reduction in the lifting force generated by an airfoil or wing. This happens as the angle of attack increases beyond what is called the critical angle of attack. The angle of attack is the coefficient of the airfoil or wing in relation to relative wind. The critical angle of attack may vary significantly depending on the design of the airfoil or wing. This is the point where the relative wind becomes disrupted to a point where the airfoil or wing ceases to provide the lift it was designed to produce. Without lift being generated by the airfoil or wing, the force of gravity overcomes the aircraft causing it to descend towards earth. The exact definition of the word stall in relation to aviation is continually debated by pilots and engineers, but simply put, a stalled aircraft loses its ability to fly.

Amateur pilots in training are taught to purposely stall the aircraft in multiple configurations or scenarios, and then initiate a recovery. Stall recovery is mandatory for every pilot's survival regardless of the airplane being flown. Two different scenarios where real life stalls most often happen are on final approach during a landing and on the climbout following a takeoff. The maneuver meant to simulate a stall on final approach while landing is called a power off stall. Typically low airspeeds during the landing sequence can increase the risk of a stall near ground level and in the final moments before landing. The power off stall is designed to teach the student to recover the aircraft before it noses into the ground causing serious injury or death. It is critical to every pilot to understand and practice recovery. The power on stall is a simulation of an aircraft taking off and possibly climbing with too much pitch. This maneuver is practiced using full throttle just as the pilot would use on takeoff. Recovery from this situation is also critical to every amateur pilot's continued existence. Another reason for airplane stalls could be wind based. Wind shear, a sudden change in wind direction or wind speed, could wreak havoc on an airplane at any time during flight however it is more common near the ground where landings and takeoffs obviously take place.

Amateur pilots are tested on their stall recovery skills during their checkride. The checkride is the final test required to earn a private pilot certificate. It consists of an oral test combined with a practical, or performance test. Knowledge and understanding of stalls and stall avoidance are always part of the oral exam. The ability to demonstrate successful stall recovery to the examiner while flying the airplane is also required to receive a private pilot certificate. Amateur pilots are always encouraged to practice stall recovery long past the test day. In the unlikely event of an actual stall while in flight, readiness and the ability to recover can be the difference between life and death of pilot and passengers.

Chet owns and operates Eye of the Pilot, an amateur pilot network dedicated to sharing the experience of general aviation and the adventure of being an amateur private pilot. You can visit Eye of the Pilot to view flight videos and aerial aviation pictures submitted by members. Account signup is always free to our amateur pilots network.

Article Source: http://EzineArticles.com/?expert=Chet_Val

What Are Some Causes That Lead To A Fear Of Flying?

What Are Some Causes That Lead To A Fear Of Flying? By Bobi MacKenzie

Bad experiences can cause flying phobias, anxiety or fears. There are many different paths that lead to developing a phobia or fear towards something. A phobia towards a specific action or object in life can be caused by any number of things in your regular routine or by something spontaneously happening to or around you.

People that have a phobia with flying may have developed the phobia simply by taking a flight on an airplane that for some reason had a lot of turbulence. There are a lot of reasons a plane might encounter turbulence. Usually there is more turbulence at night. Weather also comes into play. Storms can bring high winds or there may have been a lot of harmless air pockets in the high altitude during that flight. Turbulence can be a normal part of flying, but it can also scare people into thinking something can go wrong and in turn cause them to acquire a phobia toward flying in the future.

It has even been proven that a phobia for flying can be caused by events that took place before, during, and after a specific flight on an airplane. Some examples could be; a fight with a spouse or loved one; a death in the family, perhaps the plane had some minor complications during the flight; an illness came about- even a bad sinus infection that causes pain on the flight can trigger severe emotional trauma. Any of these may cause a person to relate these undesirable accounts with flying and develop a phobia for flying.

If a person becomes ill or upset at the time of a flight they may remember being ill and blame it on the flight or think it had something to do with food on the flight or perhaps something they drank at the time. They may think if they go on another flight they could get sick again.

Phobias for the fear of flying can be treated or even cured. People can visit with a doctor or specialist and work to find out what the specific trigger causing their phobia is to figure out a way to either deal with it or get rid of the phobia all together. Another suggestion comes from hypnosis or retraining your mind to overcome the fear. In my ebook I have offered several different methods you can work on this to help you eliminate your fears for good.

People can get medications from a doctor to suppress their fears or phobias to be able to fly. They can also use some different techniques to try to get rid of their phobia. People can prepare themselves and make things comfortable so before their flight they are in a very happy and relaxed mood. If your phobia is cause by a specific event or moment in your life you may be able to reverse the feelings causing the phobia by doing the exact opposite of the event or moment in your life. Also you may feel better by listening to some other people who enjoy or have had good experiences with flying.

If you need more information or would like to eliminate your fear of flying for good, please visit us at: Cure Flying Phobia.com

Article Source: http://EzineArticles.com/?expert=Bobi_MacKenzie

Fear of Flying

Fear of Flying By Shanat Kuphur

Flying is a beautiful experience however there are many people who are really scared and are not able to enjoy this beautiful experience. The fear of flying may be generated because of many reasons. This includes fearing the aircraft, glider or a helicopter and expecting it to crash. Fear of flying could even be initiated because of related fears. This is very true if one is scared of heights because then you won't enjoy flying. There are also many scientific reasons for the same type of fear; however the primary reason is the fear of heights or the phobia of not being stable in the air. There is also a possibility that one may feel sick and dizzy when flying.

Many people land up vomiting or even getting air sick even when they are travelling by an air plane from one destination to the other. This may not cause a problem as there are many other means of transport available for travelling but if one has a job wherein travelling on a regular basis is a requirement then it may be difficult to strike a balance. This phobia or fear of flying is purely a psychological aspect and this phobia can be easily treated. This may take longer for different individuals depending on various psychological and social factors.

Science has determined that this psychological fear of flying is largely related to other phobias. This includes suffocation in the air plane, the feeling of death, and so on. This may sound unreal to many who do not have this fear but to those who have this fear it may be a very serious topic to discuss upon. There are many ways to get over this condition. You could embrace the whole concept of flying, joining a flying club could help. However you may not be able to start off until you can deal with it in your mind.

If one is scared or is so scared that one does not even want to try flying then for such people to help overcome the fear of flying here is a simple step. All one would needs to do is get a MP3 for hypnotherapy and sit at the leisure of home and understand and do as the compact disc asks one to perform and then one may easily overcome the fear of flying. To get this compact disc one does not have to go to a psychiatrist, all one has to do is connect to the Internet and this is very easy. Download the content and one shall be able to resolve the issue very easily. Hypnotherapy for fear of flying can help you overcome this fear and there will soon come a time when you will be able to fly just as you please. The great thing about such sessions is that you will soon be mentally strong and ready to take the next flight. Don't let fear make you hold back because your inner strength can help you conquer the highest mountains so fly there today.

For more information on fear of flying and overcoming fear of flying, why not visit the links.

Article Source: http://EzineArticles.com/?expert=Shanat_Kuphur

Variometer

From Wikipedia, the free encyclopedia

The term Variometer also refers to a type of variable electrical inductor

A variometer (also known as a rate-of-climb indicator, a vertical speed indicator (VSI),^[1] or a vertical velocity indicator (VVI)) is an instrument in an aircraft used to inform the pilot of the instantaneous rate of descent or climb. It can be calibrated in knots, feet per minute (101.333 ft/min = 1 kn) or metres per second, depending on country and type of aircraft.

In powered flight the pilot makes frequent use of the VSI to ascertain that level flight is being maintained, especially during turning manoeuvres. In gliding, the instrument is used almost continuously during normal flight, often with an audible output, to inform the pilot of rising or sinking air. The instrument is of little interest during launching and landing, with the exception of aerotow, where the pilot will usually want to avoid releasing in sink.

Variometer for Paragliders, Hang Gliders and Ballooneers

Contents [hide] 1 Description 2 Purpose 3 Total Energy Compensation 3.1 Total Energy Compensation in Theory 3.2 Total Energy Compensation in practice 4 Netto Variometer 5 Electronic variometers 6 Radio controlled soaring 7 References 8 External links

Description

Schematic drawing of the internals of a classic aircraft variometer

Variometers measure the rate of change of altitude by detecting the change in air pressure (static pressure) as altitude changes. A simple variometer can be constructed by adding a large reservoir (a thermos bottle) to augment the storage capacity of a common aircraft rate-of-climb instrument. In its simplest electronic form, the instrument consists of an air bottle connected to the external atmosphere through a sensitive air flow meter. As the aircraft changes altitude, the atmospheric pressure outside the aircraft changes and air flows into or out of the air bottle to equalise the pressure inside the bottle and outside the aircraft. The rate and direction of flowing air is measured by the cooling of one of two self-heating thermistors and the difference between the thermistor resistances will cause a voltage difference; this is amplified and displayed to the pilot. The faster the aircraft is ascending (or descending), the faster the air flows. Air flowing out of the bottle indicates that the altitude of the aircraft is increasing. Air flowing into the bottle indicates that the aircraft is descending.

Newer variometer designs directly measure the static pressure of the atmosphere using a pressure sensor and detect changes in altitude directly from the change in air pressure instead of by measuring air flow. These designs tend to be smaller as they do not need the air bottle. They are more reliable as there is no bottle to be affected by changes in temperature and less opportunity for leaks to occur in the connecting tubes.

The designs described above, which measure the rate of change of altitude by automatically detecting the change in static pressure as the aircraft changes altitude are referred to as "uncompensated" variometers. The term "vertical speed indicator"^[1] or "VSI" is most often used for the instrument when it is installed in a powered aircraft. The term "variometer" is most often used when the instrument is installed in a glider or sailplane.

An "Inertia lead" VSI or ILVSI compensates for relative "g" forces experienced in a turn (powered aircraft) and provides appropriate mechanical compensation to remove otherwise erroneous indications of climb or descent.

Panel mounted variometer for gliders

Purpose

Human beings, unlike birds and other flying animals, are not able directly to sense climb and sink rates. Before the invention of the variometer, sailplane pilots found it very hard to soar. Although they could readily detect abrupt changes in vertical speed ("in the seat of the pants"), their senses did not allow them to distinguish lift from sink, or strong lift from weak lift. The actual climb/sink rate could not even be guessed at, unless there was some clear fixed visual reference nearby. Being near a fixed reference means being near to a hillside, or to the ground. Except when hill-soaring (exploiting the lift close to the up-wind side of a hill), these are generally very unprofitable positions for glider pilots to be in. The most useful forms of lift (thermal and wave lift) are found at higher altitudes and it is very hard for a pilot to detect or exploit them without the use of a variometer. After the variometer was invented in 1929 by Alexander Lippisch and Robert Kronfeld^[2], the sport of gliding moved into a new realm.

The vertical speed indicator from a Robinson R22

Total Energy Compensation

As the sport developed, however, it was found that these very simple "uncompensated" instruments had their limitations. The information that glider pilots really need to soar is the vertical speed of the glider in isolation of stick thermals, i.e., in isolation of changes in altitude due exclusively to changes in speed.

When the pilot chooses to pull up to enter a thermal or to dive to exit a sink area, an uncompensated variometer will include the change in altitude due to the change in velocity in its read-out, thus marring the airmass' climb or sink rate. Therefore an uncompensated variometer can only accurately indicate the climb rate when flying at constant speed.

The action of diving or pulling up affects the speed of the sailplane. A sailplane can exchange height for speed or speed for height, i.e. potential energy for kinetic energy or kinetic energy for potential energy. In fact, in still air, the sum of potential energy and kinetic energy, i.e., the Total Energy, remains constant (neglecting energy loss due to drag), hence the name Total Energy compensation.

Most modern sailplanes are equipped with Total Energy compensated variometers.

Total Energy Compensation in Theory

While the driving principle is:

1. Potential Energy + Kinetic Energy = Total Energy

the compensation to cancel stick thermals is:

2. Potential Energy Gained = Kinetic Energy Lost (stick thermal)

i.e.:

3. ΔE_pot = − ΔE_kin

or

4. ΔE_pot + ΔE_kin = 0

Since

5. Potential Energy is proportional to Height ()

and

6. Kinetic Energy is proportional to Velocity squared (),

then from (3):

7.

where

8. Δh is the compensation to apply to the uncompensated variometer reading.

The Vertical Speed Indicator in this Van’s RV-4 light aircraft is on the top row, on the right.

Total Energy Compensation in practice

In most sailplanes, total energy compensation is achieved by connecting the variometer to the atmosphere via a "total energy probe", that produces vacuum proportional to the square of the glider's air speed - in effect, a negative pitot. Alternatively, the subtraction may be done electronically by the flight computer based on indicated airspeed (pitot).

Very few powered aircraft have total energy variometers. The pilot of a powered aircraft is more interested in the true rate of change of altitude, as he often wants to hold a constant altitude or maintain a steady climb or descent.

The total energy probe used to be shaped as a classical venturi (two small funnels connected back-to-back by their narrow ends), or nowadays simply as a slot or pair of holes on the back side of a quarter inch vertical tube. The geometry of the TE probe is such that air flow generates suction (reduced pressure).

To maximise the precision of this compensation effect, the TE probe needs to be in undisturbed airflow ahead of the aircraft nose or tail fin (the "Braunschweig tube", the long cantilevered tube with a kink in the end that can be seen projecting from the leading edge of the tail fin on most modern sailplanes.)

Netto Variometer

A second type of compensated variometer is the Netto or airmass variometer. In addition to TE compensation, the Netto variometer adjusts for the intrinsic sink rate of the glider at a given speed (the polar curve) adjusted for the wing loading due to water ballast. The Netto variometer will always read zero in still air. This provides the pilot with the accurate measurement of air mass vertical movement critical for final glides.

The Relative Netto Variometer indicates the vertical speed the glider would achieve IF it flies at thermalling speed - independent of current air speed and attitude. This reading is calculated as the Netto reading minus the glider's minimum sink.

When the glider circles to thermal, the pilot needs to know the glider's vertical speed instead of that of the air mass. The Relative Netto Variometer (or sometimes the super Netto) includes a g-sensor to detect thermalling.

When thermalling, the sensor will detect acceleration (gravity plus centrifugal) above 1 g and tell the relative netto variometer to stop subtracting the sailplane's wing load-adjusted polar sink rate for the duration. Some earlier nettos used a manual switch instead of the g sensor.

Electronic variometers

In modern gliders, most electronic variometers generate a sound whose pitch and rhythm depends on the instrument reading. Typically the audio tone increases in frequency as the variometer shows a higher rate of climb and decreases in frequency towards a deep groan as the variometer shows a faster rate of descent. When the variometer is showing a climb, the tone is often chopped, while during a descent the tone is not chopped and the rate of chopping may be increased as the climb rate increases. The vario is typically silent in still air or in lift which is weaker than the typical sink rate of the glider at minimum sink. This audio signal allows the pilot to concentrate on the external view instead of having to watch the instruments, thus improving safety and also giving the pilot more opportunity to search for promising looking clouds and other signs of lift. A variometer that produces this type of audible tone is known as an "audio variometer".

Advanced electronic variometers in gliders can present other information to the pilot from GPS receivers. The display can thus show the bearing, distance and height required to reach an objective. In cruise mode (used in straight flight), the vario can also give an audible indication of the correct speed to fly depending on whether the air is rising or sinking. The pilot merely has to input the estimated MacCready setting, which is the expected rate of climb in the next acceptable thermal.

There is an increasing trend for advanced variometers in gliders to present other information such as controlled airspace, lists of turnpoints and even collision warnings. Some will also store positional data during the flight for later analysis.

Radio controlled soaring

Variometers are also used in radio controlled gliders. Typically it takes the form of a radio transmitter in the plane, and a receiver held by the pilot on the ground. Depending on the design, the receiver may give the pilot the current altitude of the plane (an altimeter) and some sort of display that indicates if the plane is gaining or losing altitude—often via a tone just like in full scale gliders. Other forms of telemetry may also be provided by the system, giving things such as airspeed and battery voltage. Varios used in radio controlled planes may or may not feature total energy compensation (the better/more expensive ones generally do.)

Variometers are strictly optional for R/C glider use—a skilled pilot can generally determine if their plane is going up or down via visual cues alone, and so the use of a variometer is often seen as a `crutch', as a replacement for skill, and many pilots prefer not to use them at all, as the tone can be distracting, and the (usually small) amount of weight added to the plane does affect performance. The use of variometers is permitted in some R/C soaring contests and prohibited in others.

Perhaps the most popular brands of R/C variometers are the Picolario and the WsTech CS Voice.

References

1. ^ ^{a b} "Vertical Speed Indicator". Aeronautical Knowledge Handbook. 18 November 2007. http://ma3naido.blogspot.com/2007/11/vertical-speed-indicator.html. Retrieved 2009-04-01.
2. ^ Michael H. Bednarek (2003). "Dreams of flight". Dreams of flight. http://books.google.com/books?id=x0uLSdn_hFUC&pg=PA71&lpg=PA71&dq=%22invented+the+variometer%22&source=bl&ots=oxdxYloDNt&sig=TlUO9Zl39wU712dF1Q4B3-q0Ay8&hl=en&ei=2ucaSr3iMZ6UMrrc8ZkP&sa=X&oi=book_result&ct=result&resnum=1. Retrieved 2009-05-25.

External links

• The Instantaneous Vertical Speed Indicator

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