Inertial Navigation System (INS)

Wg Cdr Rajagopal

Inertial Navigation System

Index

Introduction to Inertial Navigation Systems

  • INS is an accurate navigational aid for pilots
  • The instrument is independent of any ground installation
  • INS is capable of world-wide operations
  • Advanced form of deduced reckoning is used in INS
  • Inertial Navigation System comprises of three parts
  • inertial navigation unit
  • Mode selector unit
  • Control and display unit

Principle of Inertial Navigation Systems

  • Accelerometers and Integrators are the core of Inertial Navigation Systems
  • High grade accelerometers provide acceleration or deceleration
  • Acceleration Integrators integrates acceleration to obtain velocity
  • Velocity integrators further integrates velocity to obtain distance gone
  • INS knows the distances travelled in North-South and East-West directions
  • Change in position of aircraft can be deduced by distance travelled

Principle of Accelerometers

  • Accelerometers are used to measure acceleration of aircraft
  • E-I bar pendulous suspension is the heart of an accelerometer
  • High magnetic permeability materials are used in E-I bar
  • Acceleration swings the pendulum off the null position due to inertia
  • E-I bar detects acceleration by measuring variation of magnetism
  • Variation signal is detected in the E bar which is sent to pick-off device
  • Current is amplified is sent to the torque motor of accelerometer
  • Torque generated restores the pendulum to the null position
  • Acceleration is calculated from the amount of restoration current

First Stage Integrators

  • Integrators are time multipliers which multiplies any value with time
  • First stage integrators calculate velocity by multiplying acceleration with time
  • Acceleration integrated in N-S gets velocity component in N-S direction
  • Acceleration integrated in E-W gets velocity component in E-W direction
  • The velocities can be compounded to get distance travelled

Second Stage Integrators

  • Second stage Integrators are also time multipliers
  • Second stage integrators calculate distance by multiplying velocity with time
  • Velocity integrated in N-S gets distance travelled in N-S direction
  • Velocity integrated in E-W gets distance travelled in E-W direction
  • Distances travelled in the N-S and E-W directions provides new position

New Latitude and Longitude

  • Latitude of new position obtained by simple addition of nautical miles
  • Considering earth to be a perfect sphere latitude calculation is simple
  • One minute corresponds to one nautical mile
  • Longitude of new position has to be obtained by finding the departure
  • Departure is the distance in nautical miles along a parallel of latitude
  • Change in longitude is a product of departure and secant of latitude
  • Secant multiplier is used to calculate the new longitude
  • Accurate latitude information is required to find the new longitude

Platform Stabilisation of INS

  • Accelerometers require a stabilised platform for accurate results
  • Non-stabilised platform will tilt the E and I bars of the accelerometer
  • Incorrect acceleration would be sensed
  • Gyro stabilised platform is used to mount the accelerometers
  • The platform keeps the accelerometers stable during aircraft manoeuvrers
  • Pitch, roll as well as the yaw movements are compensated
  • Gyro stabilisation maintains the INS platform horizontal to the surface of earth

Construction of Stabilised Platform

  • Gyro stabilised platform uses three horizontal axis gyroscopes
  • Spin axis of the gyros are mutually perpendicular to each other
  • Gyros have single degree of freedom and are connected to motors
  • Rate integrating space gyroscopes are used in the stabilised platform
  • Gimbals are shaped like sealed cans floating within each other
  • Viscous liquid is used to reduce the bearing torques
  • Gyros act like two degree of freedom gyroscopes
  • Accelerometers on the platform are maintained horizontal to earth surface
  • Stable platform corrects for apparent wander due to earth rate and transport

Correction for Gyro Wander

  • Errors due to real as well as apparent gyro wander have to be corrected
  • Gyro wander is also classified as drift and topple
  • Real wander is caused due manufacturing imperfections
  • Real drift is almost eliminated in a perfect gyroscope
  • Platform stabilisation corrects for aircraft manoeuvres
  • Apparent drift and topple are to be corrected for correct functioning
  • Earth rate and Transport are the causes of apparent wander

Earth Rate Correction

  • Gyro stabilised platform has to be maintained horizontal to earth surface
  • Computed earth rate has to be corrected using a feed back mechanism
  • Feed back provides inputs to gyro stabilised platform
  • Earth rate wander can be resolved into two components
  • Horizontal component is 15 times sin of latitude in degrees per hour
  • Vertical component is 15 times cos of latitude in degrees per hour
  • These values ate fed to the platform to correct for earth rate

Transport Wander Correction

  • Transport wander corrections are applied due to movement of aircraft
  • Horizontal component of transport wander is equal to product of
  • One sixtieth of easterly component of aircraft velocity and tan of latitude
  • Vertical component is corrected using an electro-mechanical feedback loop
  • North south component of velocity divided by the radius of earth
  • Schuler tuning is used to correct vertical component of transport wander

Coriolis Force and Central Acceleration

  • INS computer computes and corrects for Coriolis and centripetal forces
  • Coriolis force and central acceleration errors have to be corrected
  • Coriolis force is caused due to acceleration of along curved meridians
  • Central acceleration is caused due centripetal force on gyroscope

Caging or Warm Up

  • Alignment of INS comprises of caging, levelling and gyro compassing
  • Caging or warm up is the first step in initial alignment, it lasts for 3 minutes
  • Frame, inner and outer gimbals are brought at 90 degrees to each other
  • Fluid filled components are heated to correct operating temperature

Coarse and Fine Levelling

  • Levelling or coarse alignment is the next in initial alignment, lasts 3 minutes
  • Levelling brings the velocity detected by accelerometers to zero
  • INS platform is made horizontal to earth surface with aircraft on chocks
  • Local gravity vector is sensed by inbuilt accelerometers
  • Feedback mechanism is used to transmit correction to levelling motor
  • Coarse levelling of the platform roughly leveling platform
  • Gravity switches and horizontal accelerometers provide inputs
  • Platform is turned within 1 to 2 degrees of aircraft heading
  • Fine levelling aligns the platform to an accuracy of 6 seconds of arc

Gyro – Compassing

  • Gyro compassing is the third step of initial alignment lasting 11 minutes
  • Spin axis of earth is sensed and platform rotated to orientate with true north
  • Earth rate provides required inputs to detect spin axis of earth
  • Gyro compassing is impossible at high latitudes higher than 70 degrees
  • Earth rate which is a factor of cosine latitude is quite low at high latitudes
  • Correct azimuth alignment would result in zero acceleration in east or west
  • Platform moves at the same velocity as earth in east west directions
  • Initial alignment is sensitive to incorrect latitude entry only
  • Incorrect longitude entry does not affect initial alignment

Schuler Period

  • Consider a pendulum suspended from earth’s surface and bob at earth’s centre
  • Length of pendulum will be equal to the radius of the earth
  • Acceleration of suspension point around the surface would keep bob vertical
  • Vertical position of the bob is due to centre of gravity of earth
  • Consider a platform mounted on the suspension point tangential to surface
  • Tangential to surface could also be called horizontal to surface
  • The pendulum would remain horizontal irrespective of the acceleration

Schuler Oscillations

  • If the bob is displaced from earth’s centre the pendulum would oscillate
  • The period of oscillation is called Schuler Period which is 84.4 minutes
  • Schuler Oscillations cause errors in the which increase and reduce with time
  • Calculated position varies from a minimum to maximum error in 84.4 minutes

Bounded Errors

  • Bounded errors increase to maximum and return to zero in a schuler cycle
  • One Schuler cycle is 84.4 minutes
  • Bounded errors are caused due to three reasons
  • Platform tilt due to initial misalignment of platform
  • Inaccurate measurement of acceleration by accelerometers
  • Integrator errors in the first stage of integration
  • Bounded errors do not increase with time but causes schuler oscillations
  • Distances measured oscillates from its mean position in a sin wave form

Un-bounded Errors

  • Unbounded or Ramp errors are outside the feedback loop
  • Ramp errors continuously increase with time in a ramp formation
  • Initial azimuth misalignment of the platform during gyro compassing
  • Acceptable misalignment is within 0.1 degrees
  • Real wander of the azimuth gyro
  • Drift rate of 1 over 100 of degree is acceptable
  • Topple rate of 1 over 100 of a degree is acceptable
  • Second stage distance integrator error
  • Calculates in correct distances for a given velocity

Cumulative Errors

  • Inertial navigation system suffers from both bounded as well as ramp errors
  • Inherent errors like the shape of earth also add up to the errors
  • The cumulative effect of all the errors would result in a sine wave pattern
  • The sine wave increases with time or distance flown
  • Better quality of manufacturing reduce errors
  • Laser Ring Gyroscopes have reduced the amount of errors

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