| 000 | 09907mm a2200421a 44500 | ||
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| 001 | NM000664 | ||
| 003 | AR-HaUTN | ||
| 005 | 20240917164013.0 | ||
| 007 | ta | ||
| 008 | 78020sc. 1 ||||||||||||||000 | spa|| | ||
| 020 | _a0-471-54795-6 | ||
| 040 |
_aAR-HaUTN _cAR-HaUTN |
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| 100 |
_aKayton, Myron _92561 |
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| 245 |
_aAvionics navigation systems _cMyron Kayton , Walter R. Fried |
||
| 250 | _a2nd ed. | ||
| 260 |
_aNew York _bJohn Wiley |
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| 300 |
_a773 p. _bgráficos |
||
| 504 | _aReferencias bibliográficas p. 705740 | ||
| 505 | _u<a href="https://biblio-intra.frh.utn.edu.ar/opac-tmpl/bootstrap/indices/664.pdf" target="_blank">Indice Alfabético </a> | ||
| 505 | _tThe navigation equations : Introduction Geometry of the Earth Coordinate Frames Dead-Reckoming Computations Positioning.Radio Fixes. Line-of-Sight Distance Measurement.Ground-Wave One-Way Ranging. Ground-Wave Time-Differencing. Terrain-Matching Navigation. Course Computation. Range and Bearing Calculation. Direct Steering. Airway Steering. Area Navigation Navigation Errors. Test Data. Geometric Dilution of Precision Digital Charts Software Development Future Trends. Problems | ||
| 505 | _tMultisensor navigation systems : Introduction Inertial System Characteristics An Integrated Stellar-Inertial System Integrated Doopler-Inertial Systems An Airspeed-Damped Inertal System An Integrated stellar-Inertal-Doopler System Position Update of an Inertial System Noninertial GPS multisensor Navigation Systems Filtering of Measurements. Single sensor. Stationary Vehicle. Multiple Sensors, Stationary vehicle. multiple Sensors, Moving Vehicle Kalman Filter Basics. The process and measurement Models. The error Covariance Matrix. The Recursive Filter Open-Loop Kalman Filter Mechanization Closed-Loop Kalman Filter Mechanization. GPS-INS Machanization.Linearizing a Nonlinear Range Measurement. GPS Clock Error Model. 11-State GPS-INS Linear Error Model. Error Model Practical considerations Federated System Architecture. Problems | ||
| 505 | _tTerrestrial radio-Navigation Systems : Introduction General Principles. Radio Transmission and Recsption. Propagation and Noise Characteristics System Design Considerations. radio-Navigation System Types. System Performance Parameters Point Source Systems. Direction-Finding. Nondirectional Beacons. Marker Beacons. VHF Omnidirectional Range (VOR). Doopler VOR. Distance-Measuring Equipment (DME). Tactical Air Navigation (Tacan). VORTAC Hyperbolic Systems. Loran. Omega. Decca. Chayka Future trends. Problems | ||
| 505 | _tSatellite radio navigation : Introduction. System Configuration The Basics of Satellite radio Navigation. Ranging Equations.Range-RATE (Change-in-Range) Equations. Clok Errors Orbital Mechanics and Clok Characteristics. Orbital Mechanics. Clok Characteristics Atmospheric Effects on Satellite Signals. Ionospheric Refraction. Tropospheric Refraction NAVSTAR Global Positioning System. Principles of GPS and System Operation. GPS Satellite Constellation and Coverage. Space Vehicle Configuration. The GPS Control Segment. GPS Signal Structure. The GPS Navigation Message. GPS Measurements and the Navigation. Solution. Aviation Receiver Characteristics. Differential GPS. GPS Accuracy Global Orbiting Navigation Satellite System. (GLONASS). GLONASS Orbits. GLONASS Signal Structure. The GLONASS Navigation Message. Time and Coordinate Systems. GLONASS Constellation GNSS Integrity and Availability. receiver Autonomous Integrity Monitoring (RAIM). Combined GPS/GLONass. Wide Area Augmentation System (WAAS). Psedolite Augmentation. Future Treds. Problems | ||
| 505 | _tTerrestrial Integrated Radio Communication-Navigation Systems : Introduction. JTIDS Relative Navigation.General Principles. JTIDS System Characteristics. Clok Synchronization. Coordinate Frames and Community Organization.Operational Utility. Mechanization. Error characteristics. System Accuracy Position Location Reporting System. General Principles. System Elements. Control Network Structure. Waverform Architecture. Measurements. PositionLocation and Tracking. Tracking Filter. Network and Traffic Management. System Capacity and Accuracy. PLRS User Equipment Characteristics. System Enhancements Future Trends. Problems | ||
| 505 | _tInertial navigation : Introduction The System Instruments. Accelerometers. Gyroscopes. Optical Gyroscopes. Mechanical Gyroscopes. Future Inertial Instruments Platforms. Analytic Platform (Strapdown). Gimballed Platform. Inertial Specifications Mechanization Equations. Coordinate Frames. Horizontal Mechanization. Vertical Mechanization Error Analysis. Purpose. Simulation. Error Propagation. Total System Error Alignment. Leveling. Gyrocompass Alignment. Transfer Alignment. Attitude and Heading Reference Systems (AHRS) Fundamental Limits Future Trens. Problems | ||
| 505 | _tAir-Data Systems : Introdution Air-Data Measurements. Conventional "Intrusive"Probes. Static Pressure. Total Pressure. Air Temperature. Angle of Attack and Angle of Sideslip. Air-Data Trasducers Air-data Equations.. Altitude. Mach Number. Calibrated Airspeed. True Airspeed. Altitude Rate Air-DataSystems. Accuracy Requirements. Air-Data Computers. Architecture Trends Specialty Designs. Helicopter Air-data Systems. Optical Air-Data Systems. Hypersonic Air-Data Calibration and System test. Ground Calibration. Flight calibration. Built-in Test (BIT) Future Trends. Problems | ||
| 505 | _tAttitude and Heading References : Introduction. Basic Instruments: Gyroscopes. Gravity Sensors Vertical references: The Averaging Vertical Reference. Rate Compensations.Acceleration Corrections. Maneuver Errors. Heading References: Earth s Magnetic Field. Aircraft Magnetic Compass Needle. Magnetometers. Electrical Swinging. The Directional Gyroscope. Initial Alignment of Heading References Future Trends Problems | ||
| 505 | _tDoppler and altimeter radars : Doppler Radars: Functions and Applications. Dopper Radar Principles and.Desing Approaches.Signal Characteristics. Doppler Radar Errors. Equipment Configurations. Radar Altimeters: Functions and Applications. General Principles. Pulsed Radar Altimeters. FM-CW Radar Altimeter. Phase-Coded Pulsed Radar Altimeters. Future Trends. Problems | ||
| 505 | _tMapping and multimode radars : Introduction. Radar Pilotage. Semiautomatic Position Fixing Semiautomatic Position Fixing with Synthetic. Aperture Radars. Unfocused Systems. Focused Systems. Motion Compensation. Precision Velocity Update: Mechanization. PVU Measurement Errors. PVU Kalman Filter. PVU Mode Observability Concerns Terrain Following and Avoidance. Radae Mode and Scan Pattern. Implementation. Terrain Measurement. Aicraft Control Multimode Radars Signal Processing Airborne Weather radar. Radar Reflectivity of Weather Formations. Wether Radar Processing. Radar Detection of Microburst and Wind Shear Future Trends Electronic Scanned Arrays radar Processing Radar Receiver/Exciter Function Interfaces and Packaging Displays Problem | ||
| 505 | _tCelestial navigation : Introduction. Evolution of Celestial Navigation. General System Description. Star Obsevation Geometry Theory of Stellar-Inertial Navigation. Modeling and Kalman Filtering. Information and Observability Stellar Sensor Desing Characteridtics. Telescope parameters Star- Signal Power. Sky background Power. Star-light Detection. Focal Plane Array Processing Celestial Navitation System Design. Time Refernce. Star Observation and Pointing Errors. Stabilized Platform Configuration. Strapdown IMU Configurations Star Catalog Characteristics. Star Catalog Contents. Star Catalog Size. Planet and Moon Avoidance. Star Position Corrections System calibration and alignment. Factory Calibration. Pre-flight and In-flight Calibration and Alignment Future Trends. Problems | ||
| 505 | _tLanding systems : Introduction. Low Visibility Operations. The Mechanics of the Landing. The Approach. The Flare Maneuver. The Decrab maneuver and Touchdown. Rollout and Taxi Automatic landing Systems. Guidance and Control Requirements. Flare Guidance. Lateral Guidance. The Instrument landing System. ILS Guidance Signal. The Localizer. The Glide Slope. ILS Marker beacons. Receivers. ILS Limitations The Microwave-landing System. Signal Format. The Angle Functions. data Functions.Aircraft Antennas and Receivers. mobile MLS. Precision DME (DME/P). Satellite landing Systems. Augmentation Concepts. position Solutions. Research Issues Carrier-landing Systems. Description of the Problem Optical landing Aids. Electronic Landing Aids Future trends. Pilot Aids. Satellite landing Aids. airport Surface navigation. carrier Landing. Problems | ||
| 505 | _tAir Traffic Management : Introduction. Services Provided to Aircraft Operators. Government Responsibilities Flight Rules and Airspace Organization. Visual and Instrument Flight Rules. Altimetry. Controlled Airspace. Uncontrolled airspace. Special Use Airspace Airways and Procedures. Victor Airways and Jet Routes. random Routes. Separation Standars. terminal Instrument departures and Arrivals Phases of Flight. pre-flight Planning. Departure. En Route. Approach and Landing. Oceanic Subsystems. Navigation. Radar surveillance. Automatic Dependent Surveillance. Air-to-Ground dta Link Communications. Aviation Weather. Automation and Display Subsystem. Airbone ATM Subsystems Facilities and Operations. National Traffic Managenent. En-route Facilities. Terminal Facilities. Aiport Facilities. Flight service Facilities. Oceanic Facilities System Capacity. Reducing Peak Demand. Increasing System Capacity Airborne Collision Avoidance Systems Future Trens Problems | ||
| 505 | _tAvionics Interfaces : Introduction. Data Buses. Crew Displays. Power. Maintenance. Physical Interface. Future Trens. Problems | ||
| 653 | _aINGENIERIA AERONAUTICA | ||
| 653 | _aAVIONICA | ||
| 700 |
_aFried, Walter R. _92562 |
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| 942 |
_cBK _2udc |
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| 999 |
_c664 _d664 |
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