Strapdown and Integrated Navigation Systems Training
|Commitment||4 days, 7-8 hours a day.|
|How To Pass||Pass all graded assignments to complete the course.|
|User Ratings||Average User Rating 4.8 See what learners said|
|Delivery Options||Instructor-Led Onsite, Online, and Classroom Live|
Strapdown and Integrated Navigation Systems Training Course – Hands-on
Strapdown and Integrated Navigation Systems Training – specifically tailored to the needs of busy engineers, scientists, managers, and aerospace professionals – ENO will provide you with new insights into the modern guidance, navigation, and control techniques now being perfected at key research centers around the globe.
The various topics are illustrated with powerful analogies, full-color sketches, block diagrams, simple one-page derivations highlighting their salient features, and numerical examples that employ inputs from today’s battlefield rockets, orbiting satellites, and deep-space missions. These lessons are carefully laid out to help you design and implement practical performance-optimal missions and test procedures.
Strapdown and Integrated Navigation Systems Training Course – Customize it
- We can adapt this training course to your group’s background and work requirements at little to no added cost.
- If you are familiar with some aspects of this training course, we can omit or shorten their discussion.
- We can adjust the emphasis placed on the various topics or build the training around the mix of technologies of interest to you (including technologies other than those included in this outline).
- If your background is nontechnical, we can exclude the more technical topics, include the topics that may be of special interest to you (e.g., as a manager or policy-maker), and present the training course in manner understandable to lay audiences.
Strapdown and Integrated Navigation Systems Training Course – Audience/Target Group
The target audience for this training course:
Strapdown and Integrated Navigation Systems Training Course – Objectives:
Upon completing this training course, learners will be able to meet these objectives:
- What are the key differences between gimballing and strapdown Intertial Navigation Systems?
- How are transfer alignment operations being carried out on modern battlefields?
- How sensitive are today’s solid state accelerometers and how are they currently being designed?
- What is a covariance matrix and how can it be used in evaluating the performance capabilities of Integrated GPS/INS Navigation Systems?
- How do the Paveway IV smart bombs differ from their predecessors?
- How are MEMS devices manufactured adn what practical functions do they perform?
- • What is the deep space network and how does it handle its demanding missions?
Strapdown and Integrated Navigation Systems Training – Course Content
Inertial Navigation Systems. Fundamental Concepts. Schuller pendulum errors. Strapdown implementations. Ring laser gyros. The Sagnac effect. Monolithic ring laser gyros. Fiber optic gyros. Advanced strapdown implementations.
Radionavigation’s Precise Position-Fixing Techniques. Active and passive radionavigation systems. Pseudoranging solutions. Nanosecond timing accuracies. The quantum-mechanical principles of cesium and rubidium atomic clocks. Solving for the user’s position.
Integrated Navigation Systems. Intertial navigation. Gimballing and strapdown navigation. Open-loop and closed-loop implementations. Transfer alignment techniques. Kalman filters and their state variable selections. Test results.
Hardware Units for Inertial Navigation. Solid-state accelerometers. Initializing today’s strapdown inertial navigation systems. Coordinate rotations and direction cosine matrices. MEMS devices. The beautiful marriage between MEMS technology and the GPS. Spaceborne inertial navigation systems.
Military Applications of Integrated Navigation. Translator implementations at military test ranges. Military performance specifications. Military test results. Tactical applications. The Trident Accuracy Improvement Program. Tomahawk cruise missiles.
Navigation Solutions and Kalman Filtering Techniques. Ultra precise navigation solutions. Solving for the user’s velocity. Evaluating the geometrical dilution of precision. Kalman filtering techniques. The covariance matrices and their physical interpretations. Typical state variable selections. Monte Carlo simulations.
Smart bombs, Guided Missiles, and Artillery Projectiles. Beam-riders and their destructive potential. Smart bombs and their demonstrated accuracies. Smart and rugged artillery projectiles. The Paveway IV smart bombs.
Spaceborne Applications of Integrated Navigation Systems. On-orbit position-fixing on early satellites. The Twin Grace satellites. Guiding tomorrow’s booster rockets. Attitude determinations for
The International Space Station. Cesium fountain clocks in space. Relativistic corrections for radionavigation satellites.
Today’s Guidance and Control for Deep Space Missions. Putting ICBM’s through their paces. Guiding tomorrow’s highly demanding missions from the Earth to Mars. JPL’s awesome new interplanetary pinball machines. JPL’s deep space network. Autonomous robots swarming along the space frontier. Driving along tomorrow’s unpaved freeways in the sky.