Density Altitude
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Fog and Low Clouds As Troublemakers During Wildfi Res
When Our Heads Are in the Clouds Sometimes water droplets do not freeze in below- Detecting fog from space Up to 60,000 ft (18,000m) freezing temperatures. This happens if they do not have Weather satellites operated by the National Oceanic The fog comes a surface (like a dust particle or an ice crystal) upon and Atmospheric Administration (NOAA) collect data on on little cat feet. which to freeze. This below-freezing liquid water becomes clouds and storms. Cirrus Commercial Jetliner “supercooled.” Then when it touches a surface whose It sits looking (36,000 ft / 11,000m) temperature is below freezing, such as a road or sidewalk, NOAA operates two different types of satellites. over harbor and city Geostationary satellites orbit at about 22,236 miles Breitling Orbiter 3 the water will freeze instantly, making a super-slick icy on silent haunches (34,000 ft / 10,400m) Cirrocumulus coating on whatever it touches. This condition is called (35,786 kilometers) above sea level at the equator. At this and then moves on. Mount Everest (29,035 ft / 8,850m) freezing fog. altitude, the satellite makes one Earth orbit per day, just Carl Sandburg Cirrostratus as Earth rotates once per day. Thus, the satellite seems to 20,000 feet (6,000 m) Cumulonimbus hover over one spot below and keeps its “birds’-eye view” of nearly half the Earth at once. Altocumulus The other type of NOAA satellites are polar satellites. Their orbits pass over, or nearly over, the North and South Clear and cloudy regions over the U.S. -
Sept. 12, 1950 W
Sept. 12, 1950 W. ANGST 2,522,337 MACH METER Filed Dec. 9, 1944 2 Sheets-Sheet. INVENTOR. M/2 2.7aar alwg,57. A77OAMA). Sept. 12, 1950 W. ANGST 2,522,337 MACH METER Filed Dec. 9, 1944 2. Sheets-Sheet 2 N 2 2 %/ NYSASSESSN S2,222,W N N22N \ As I, mtRumaIII-m- III It's EARAs i RNSITIE, 2 72/ INVENTOR, M247 aeawosz. "/m2.ATTORNEY. Patented Sept. 12, 1950 2,522,337 UNITED STATES ; :PATENT OFFICE 2,522,337 MACH METER Walter Angst, Manhasset, N. Y., assignor to Square D Company, Detroit, Mich., a corpora tion of Michigan Application December 9, 1944, Serial No. 567,431 3 Claims. (Cl. 73-182). is 2 This invention relates to a Mach meter for air plurality of posts 8. Upon one of the posts 8 are craft for indicating the ratio of the true airspeed mounted a pair of serially connected aneroid cap of the craft to the speed of sound in the medium sules 9 and upon another of the posts 8 is in which the aircraft is traveling and the object mounted a diaphragm capsuler it. The aneroid of the invention is the provision of an instrument s: capsules 9 are sealed and the interior of the cas-l of this type for indicating the Mach number of an . ing is placed in communication with the static aircraft in fight. opening of a Pitot static tube through an opening The maximum safe Mach number of any air in the casing, not shown. The interior of the dia craft is the value of the ratio of true airspeed to phragm capsule is connected through the tub the speed of sound at which the laminar flow of ing 2 to the Pitot or pressure opening of the Pitot air over the wings fails and shock Waves are en static tube through the opening 3 in the back countered. -
E6bmanual2016.Pdf
® Electronic Flight Computer SPORTY’S E6B ELECTRONIC FLIGHT COMPUTER Sporty’s E6B Flight Computer is designed to perform 24 aviation functions and 20 standard conversions, and includes timer and clock functions. We hope that you enjoy your E6B Flight Computer. Its use has been made easy through direct path menu selection and calculation prompting. As you will soon learn, Sporty’s E6B is one of the most useful and versatile of all aviation computers. Copyright © 2016 by Sportsman’s Market, Inc. Version 13.16A page: 1 CONTENTS BEFORE USING YOUR E6B ...................................................... 3 DISPLAY SCREEN .................................................................... 4 PROMPTS AND LABELS ........................................................... 5 SPECIAL FUNCTION KEYS ....................................................... 7 FUNCTION MENU KEYS ........................................................... 8 ARITHMETIC FUNCTIONS ........................................................ 9 AVIATION FUNCTIONS ............................................................. 9 CONVERSIONS ....................................................................... 10 CLOCK FUNCTION .................................................................. 12 ADDING AND SUBTRACTING TIME ....................................... 13 TIMER FUNCTION ................................................................... 14 HEADING AND GROUND SPEED ........................................... 15 PRESSURE AND DENSITY ALTITUDE ................................... -
Beforethe Runway
EDITORIAL Before the runway By Professor Sidney dekker display with fl ight information. My airspeed is leaking out of Editors Note: This time, we decided to invite some the airplane as if the hull has been punctured, slowly defl at- comments on Professor Dekker’s article from subject ing like a pricked balloon. It looks bizarre and scary and the matter experts. Their responses follow the article. split second seems to last for an eternity. Yet I have taught myself to act fi rst and question later in situations like this. e are at 2,000 feet, on approach to the airport. The big So I act. After all, there is not a whole lot of air between me W jet is on autopilot, docile, and responsively follow- and the hard ground. I switch off the autothrottle and shove ing the instructions I have put into the various computer the thrust levers forward. From behind, I hear the engines systems. It follows the heading I gave it, and stays at the screech, shrill and piercing. Airspeed picks up. I switch off altitude I wanted it at. The weather is alright, but not great. the autopilot for good measure (or good riddance) and fl y Cloud base is around 1000 feet, there is mist, a cold driz- the jet down to the runway. It feels solid in my hands and zle. We should be on the ground in the next few minutes. docile again. We land. Then everything comes to a sudden I call for fl aps, and the other pilot selects them for me. -
Aviation Glossary
AVIATION GLOSSARY 100-hour inspection – A complete inspection of an aircraft operated for hire required after every 100 hours of operation. It is identical to an annual inspection but may be performed by any certified Airframe and Powerplant mechanic. Absolute altitude – The vertical distance of an aircraft above the terrain. AD - See Airworthiness Directive. ADC – See Air Data Computer. ADF - See Automatic Direction Finder. Adverse yaw - A flight condition in which the nose of an aircraft tends to turn away from the intended direction of turn. Aeronautical Information Manual (AIM) – A primary FAA publication whose purpose is to instruct airmen about operating in the National Airspace System of the U.S. A/FD – See Airport/Facility Directory. AHRS – See Attitude Heading Reference System. Ailerons – A primary flight control surface mounted on the trailing edge of an airplane wing, near the tip. AIM – See Aeronautical Information Manual. Air data computer (ADC) – The system that receives and processes pitot pressure, static pressure, and temperature to present precise information in the cockpit such as altitude, indicated airspeed, true airspeed, vertical speed, wind direction and velocity, and air temperature. Airfoil – Any surface designed to obtain a useful reaction, or lift, from air passing over it. Airmen’s Meteorological Information (AIRMET) - Issued to advise pilots of significant weather, but describes conditions with lower intensities than SIGMETs. AIRMET – See Airmen’s Meteorological Information. Airport/Facility Directory (A/FD) – An FAA publication containing information on all airports, seaplane bases and heliports open to the public as well as communications data, navigational facilities and some procedures and special notices. -
Air Data Computer 8EB3AAA1 DESCRIPTION AMETEK Has Designed a Compact, Solid State Air Data Computer for Military Applications
Air Data Computer 8EB3AAA1 DESCRIPTION AMETEK has designed a compact, solid state Air Data Computer for military applications. The Air Data Computer utilizes a digital signal processor for fast calculation and response of air data parameters. Silicon pressure transducers provide the static and Pitot pressure values and are easily replaced without calibration. The AMETEK Air Data Computer incorporates a unique power supply that allows the unit to operate through 5 second power interrupts when at any input voltage in its operating range. This ensures that critical air data parameters reach the cockpit and control systems under a FEATURES wide variety of conditions. 3 The MIL-STD-1553 interface 40 ms update rate Thirteen (13) different air data parameters are provided on the MIL-STD- 3 11-bit reported pressure 1553B interface and are calculated by the internal processor at a 40 ms rate. altitude interface 3 AOA and total temperature An 11-bit reported pressure altitude interface encoded per FAA order inputs 1010.51A is available for Identification Friend or Foe equipment. 3 Low weight: 2.29 lbs. 3 Small size: 6.81” x 6.0” x 2.5” 3 Low power: 1.5 watts 3 DO-178B level A software AEROSPACE & DEFENSE Air Data Computer 8EB3AAA1 SPECIFICATIONS PERFORMANCE CHARACTERISTICS Air Data Parameters Power: DO-160, Section 16 Cat Z or MIL-STD-704A-F • ADC Altitude Rate Output (Hpp or dHp/dt) 5 second power Interruption immunity at any • True Airspeed Output (Vt) input voltage • Calibrated Airspeed Output (Vc) Power Consumption: 1.5 watts • Indicated Airspeed Output (IAS) Operating Temperature: -55°C to +71°C; 1/2 hour at +90°C • Mach Number Output (Mt) Weight: 2.29 lbs. -
Density Altitude
Federal Aviation Administration Density Altitude FAA–P–8740–2 • AFS–8 (2008) HQ-08561 Density Altitude Note: This document was adapted from the original Pamphlet P-8740-2 on density altitude. Introduction Although density altitude is not a common subject for “hangar flying” discussions, pilots need to understand this topic. Density altitude has a significant (and inescapable) influence on aircraft and engine performance, so every pilot needs to thoroughly understand its effects. Hot, high, and humid weather conditions can cause a routine takeoff or landing to become an accident in less time than it takes to tell about it. Density Altitude Defined Types of Altitude Pilots sometimes confuse the term “density altitude” with other definitions of altitude. To review, here are some types of altitude: • Indicated Altitude is the altitude shown on the altimeter. • True Altitude is height above mean sea level (MSL). • Absolute Altitude is height above ground level (AGL). • Pressure Altitude is the indicated altitude when an altimeter is set to 29.92 in Hg (1013 hPa in other parts of the world). It is primarily used in aircraft performance calculations and in high-altitude flight. • Density Altitude is formally defined as “pressure altitude corrected for nonstandard temperature variations.” Why Does Density Altitude Matter? High Density Altitude = Decreased Performance The formal definition of density altitude is certainly correct, but the important thing to understand is that density altitude is an indicator of aircraft performance. The term comes from the fact that the density of the air decreases with altitude. A “high” density altitude means that air density is reduced, which has an adverse impact on aircraft performance. -
Solar Energy Generation Model for High Altitude Long Endurance Platforms
Solar Energy Generation Model for High Altitude Long Endurance Platforms Mathilde Brizon∗ KTH - Royal Institute of Technology, Stockholm, Sweden For designing and evaluating new concepts for HALE platforms, the energy provided by solar cells is a key factor. The purpose of this thesis is to model the electrical power which can be harnessed by such a platform along any flight trajectory for different aircraft designs. At first, a model of the solar irradiance received at high altitude will be performed using the solar irradiance models already existing for ground level applications as a basis. A calculation of the efficiency of the energy generation will be performed taking into account each solar panel's position as well as shadows casted by the aircraft's structure. The evaluated set of trajectories allows a stationary positioning of a hale platform with varying wind conditions, time of day and latitude for an exemplary aircraft configuration. The qualitative effects of specific parameter changes on the harnessed solar energy is discussed as well as the fidelity of the energy generation model results. Nomenclature δ Solar declination ({) EQE Quantum efficiency (%) η Efficiency (%) hg Altitude of the aircraft (m) ◦ Γ Day angle ( ) hO3 Height of max ozone concentration(m) ◦ −2 −1 λg Longitude aircraft ( ) Id Direct irradiance (W:m .µm ) ◦ −2 −1 ! Hour angle ( ) Is Diffuse irradiance (W:m .µm ) ◦ −2 −1 φg Latitude of the aircraft ( ) Itot Total irradiance (W:m .µm ) ◦ −1 ◦ τ Rayleigh optical depth ({) kPmax;T Temperature Coefficient (%: C ) 2 A Solar cell -
16.00 Introduction to Aerospace and Design Problem Set #3 AIRCRAFT
16.00 Introduction to Aerospace and Design Problem Set #3 AIRCRAFT PERFORMANCE FLIGHT SIMULATION LAB Note: You may work with one partner while actually flying the flight simulator and collecting data. Your write-up must be done individually. You can do this problem set at home or using one of the simulator computers. There are only a few simulator computers in the lab area, so not leave this problem to the last minute. To save time, please read through this handout completely before coming to the lab to fly the simulator. Objectives At the end of this problem set, you should be able to: • Take off and fly basic maneuvers using the flight simulator, and describe the relationships between the control yoke and the control surface movements on the aircraft. • Describe pitch - airspeed - vertical speed relationships in gliding performance. • Explain the difference between indicated and true airspeed. • Record and plot airspeed and vertical speed data from steady-state flight conditions. • Derive lift and drag coefficients based on empirical aircraft performance data. Discussion In this lab exercise, you will use Microsoft Flight Simulator 2000/2002 to become more familiar with aircraft control and performance. Also, you will use the flight simulator to collect aircraft performance data just as it is done for a real aircraft. From your data you will be able to deduce performance parameters such as the parasite drag coefficient and L/D ratio. Aircraft performance depends on the interplay of several variables: airspeed, power setting from the engine, pitch angle, vertical speed, angle of attack, and flight path angle. -
1 the Atmosphere of Pluto As Observed by New Horizons G
The Atmosphere of Pluto as Observed by New Horizons G. Randall Gladstone,1,2* S. Alan Stern,3 Kimberly Ennico,4 Catherine B. Olkin,3 Harold A. Weaver,5 Leslie A. Young,3 Michael E. Summers,6 Darrell F. Strobel,7 David P. Hinson,8 Joshua A. Kammer,3 Alex H. Parker,3 Andrew J. Steffl,3 Ivan R. Linscott,9 Joel Wm. Parker,3 Andrew F. Cheng,5 David C. Slater,1† Maarten H. Versteeg,1 Thomas K. Greathouse,1 Kurt D. Retherford,1,2 Henry Throop,7 Nathaniel J. Cunningham,10 William W. Woods,9 Kelsi N. Singer,3 Constantine C. C. Tsang,3 Rebecca Schindhelm,3 Carey M. Lisse,5 Michael L. Wong,11 Yuk L. Yung,11 Xun Zhu,5 Werner Curdt,12 Panayotis Lavvas,13 Eliot F. Young,3 G. Leonard Tyler,9 and the New Horizons Science Team 1Southwest Research Institute, San Antonio, TX 78238, USA 2University of Texas at San Antonio, San Antonio, TX 78249, USA 3Southwest Research Institute, Boulder, CO 80302, USA 4National Aeronautics and Space Administration, Ames Research Center, Space Science Division, Moffett Field, CA 94035, USA 5The Johns Hopkins University Applied Physics Laboratory, Laurel, MD 20723, USA 6George Mason University, Fairfax, VA 22030, USA 7The Johns Hopkins University, Baltimore, MD 21218, USA 8Search for Extraterrestrial Intelligence Institute, Mountain View, CA 94043, USA 9Stanford University, Stanford, CA 94305, USA 10Nebraska Wesleyan University, Lincoln, NE 68504 11California Institute of Technology, Pasadena, CA 91125, USA 12Max-Planck-Institut für Sonnensystemforschung, 37191 Katlenburg-Lindau, Germany 13Groupe de Spectroscopie Moléculaire et Atmosphérique, Université Reims Champagne-Ardenne, 51687 Reims, France *To whom correspondence should be addressed. -
Radar Altimeter True Altitude
RADAR ALTIMETER TRUE ALTITUDE. TRUE SAFETY. ROBUST AND RELIABLE IN RADARDEMANDING ENVIRONMENTS. Building on systems engineering and integration know-how, FreeFlight Systems effectively implements comprehensive, high-integrity avionics solutions. We are focused on the practical application of NextGen technology to real-world operational needs — OEM, retrofit, platform or infrastructure. FreeFlight Systems is a community of respected innovators in technologies of positioning, state-sensing, air traffic management datalinks — including rule-compliant ADS-B systems, data and flight management. An international brand, FreeFlight Systems is a trusted partner as well as a direct-source provider through an established network of relationships. 3 GENERATIONS OF EXPERIENCE BEHIND NEXTGEN AVIONICS NEXTGEN LEADER. INDUSTRY EXPERT. TRUSTED PARTNER. SHAPE THE SKIES. RADAR ALTIMETERS FreeFlight Systems’ certified radar altimeters work consistently in the harshest environments including rotorcraft low altitude hover and terrain transitions. RADAROur radar altimeter systems integrate with popular compatible glass displays. AL RA-4000/4500 & FreeFlight Systems modern radar altimeters are backed by more than 50 years of experience, and FRA-5500 RADAR ALTIMETERS have a proven track record as a reliable solution in Model RA-4000 RA-4500 FRA-5500 the most challenging and critical segments of flight. The TSO and ETSO-approved systems are extensively TSO-C87 l l l deployed worldwide in helicopter fleets, including ETSO-2C87 l l l some of the largest HEMS operations worldwide. DO-160E l l l DO-178 Level B l Designed for helicopter and seaplane operations, our DO-178B Level C l l radar altimeters provide precise AGL information from 2,500 feet to ground level. -
Digital Air Data Computer Type Ac32
DIGITAL AIR DATA COMPUTER TYPE AC32 GENERAL THOMMEN is a leading manufacturer of Air Data Systems It also supports the Air Data for enhanced safety and aircraft instruments used worldwide on a full range infrastructure capabilities for Transponders and an ICAO aircraft types from helicopters to corporate turbine aircraft encoded altitude output is also available as an option. and commercial airliners. The AC32 measures barometric altitude, airspeed and temperature in the atmosphere with Its power supply is designed for 28 VDC. The low power integrated vibrating cylinder pressure sensors with high consumption of less than 7 Watts and its low weight of only accuracy and stability for both static and pitot ports. 2.2 Ibs (1000 grams) have been optimized for applications in state-of-the-art avionics suites. The extensive Built-in-Test The THOMMEN AC32 Digital Air Data Computer exceeds FAA capability guarantees safe operation. Technical Standard Order (TSO) and accuracy requirements. The computed air data parameters are transmitted via the The AC32 is designed to be modular which allows easy configurable ARINC 429 data bus. There are two ARINC 429 maintenance by the operator thanks to the RS232 transmit channels and two receive channels with which baro maintenance interface. The THOMMEN AC32 can be confi correction can be accomplished also. gured for different applications and has excellent hosting capabilities for supplying data to next generation equipment The AC32 meets the requirements for multiple platforms for without altering the system architecture. TAWS, ACAS/TCAS, EGPWS or FMS systems. For customized versions please contact THOMMEN AIRCRAFT EQUIPMENT AG sales department.