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Day 48, Tuesday, 3 November, 2015 Inertial Navigation Systems The magical, mysterious, always everywhere box The ball in the trunk Dead Reckoning: Direction.

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Presentation on theme: "Day 48, Tuesday, 3 November, 2015 Inertial Navigation Systems The magical, mysterious, always everywhere box The ball in the trunk Dead Reckoning: Direction."— Presentation transcript:

1 Day 48, Tuesday, 3 November, 2015 Inertial Navigation Systems The magical, mysterious, always everywhere box The ball in the trunk Dead Reckoning: Direction and Distance Roll, Pitch, Yaw and X, Y, Z Gyroscopes Mechanical Optical Accelerometers iPhone Inertial Navigation Units

2 Important motion equations avg v = ∆d/∆t = d f – d i / t f - t i avg a = ∆v/∆t = v f – v i / t f – t i d = d 0 + v t position with constant velocity d = d 0 + v 0 t + ½ a t 2 position with constant acceleration v = v 0 + a t velocity with constant acceleration d = d 0 + ½ (v + v 0 )t final position with constant velocity v 2 = v 0 2 + 2 a (d – d 0 ) final velocity with constant acc tan = opp /adj direction of travel

3 Newton’s 3 Laws of Motion 1. Inertia: An object at rest will remain at rest. An object moving will move in a straight line with constant speed, if and only if the net force acting on it = 0. 2. F = ma 3. F a on b = -F b on a (for every action there is an = and opposite reaction)

4 A Ball in the Trunk

5 Dead Reckoning Direction Distance

6 Roll, Pitch, and Yaw

7 X, Y, Z Roll, Pitch, Yaw

8 Gyroscope Inertia keeps the spinning mass from moving out of the plane of rotation

9 Gyroscopic Stabilization Gyroscopic Stabilization is how bicycles stay up Old navy trick

10 An “Artificial Horizon” is a Mechanical Gyroscope

11 Optical gyroscopes Ring Laser gyroscope Fiber Optic Loop gyroscope

12 Inertial Navigation Unit using Gyroscopes and accelerometers Gyroscope (roll)  differentiating circuit Gyroscope (pitch)  differentiating circuit Gyroscope (yaw)  differentiating circuit Accelerometer (X)  integrating circuit Accelerometer (Y)  integrating circuit Accelerometer (Z)  integrating circuit

13 Circuits can Differentiate and Integrate

14 Differentiating Circuit

15 Integrating Circuit

16 Inertial Navigation System

17 Accelerometer on a microchip

18 The engineering term is “catastrophic failure”

19 Credits INS http://www.fauskes.net/media/pgftikzexam ples/PNG/inertial-navigation-system.png Differenitating and Integrating Circuits http://www.physics.ucla.edu/demoweb/de momanual/electricity_and_magnetism/ac_c ircuits/rc_integration_and_differentiation.ht ml

20 Credits II Gyroscope diagram http://innergyro.com/images/800px- 3D_Gyroscope%5B1%5D.png X, Y, Z and Roll, Pitch, Yaw diagram http://developer.valvesoftware.com/w/ima ges/7/7e/Roll_pitch_yaw.gif

21 Credits III Artificial Horizon http://www.computermuseum.li/Testpage/Sperry HorizonIndicatorGyroscope.jpg Accelerometer on a microchip http://clifton.mech.northwestern.edu/~me381/Gyr oscope.gif Ring Laser gyroscope http://media-2.web.britannica.com/eb- media/16/78616-004-BDBE9561.jpg

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