Where am I? Sensors and Methods for Mobile Robot Positioning
Where am I? Sensors and Methods for Mobile Robot Positioning
Where am I? Sensors and Methods for Mobile Robot Positioning
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38 Part I <strong>Sensors</strong> <strong>for</strong> <strong>Mobile</strong> <strong>Robot</strong> <strong>Positioning</strong><br />
<strong>am</strong>ount of backscatter will always be present. Martin [1986] reports a representative value as 10 -12<br />
of the power of the main be<strong>am</strong>; enough to induce frequency lock-in <strong>for</strong> rotational rates of several<br />
hundred degrees per hour in a typical gyro with a 20-centimeter (8-in) perimeter.<br />
A<br />
B<br />
C<br />
D<br />
Figure 2.6: Six-mirror configuration of three-axis ring-laser<br />
gyro. (Adapted from [Koper, 1987].)<br />
An additional technique <strong>for</strong> reducing lock-in is to incorporate some type of biasing scheme to shift<br />
the operating point away from the deadb<strong>and</strong> zone. Mechanical dithering is the least elegant but most<br />
common biasing means, introducing the obvious disadvantages of increased system complexity <strong>and</strong><br />
reduced mean time between failures due to the moving parts. The entire gyro assembly is rotated<br />
back <strong>and</strong> <strong>for</strong>th about the sensing axis in an oscillatory fashion. State-of-the-art dithered active ring<br />
laser gyros have a scale factor linearity that far surpasses the best mechanical gyros.<br />
Dithered biasing, un<strong>for</strong>tunately, is too slow <strong>for</strong> high-per<strong>for</strong>mance systems (i.e., flight control),<br />
resulting in oscillatory instabilities [Martin, 1986]. Furthermore, mechanical dithering can introduce<br />
crosstalk between axes on a multi-axis system, although some unibody three-axis gyros employ a<br />
common dither axis to eliminate this possibility [Martin, 1986].<br />
Buholz <strong>and</strong> Chodorow [1967], Chesnoy [1989], <strong>and</strong> Christian <strong>and</strong> Rosker [1991] discuss the use<br />
of extremely short duration laser pulses (typically 1/15 of the resonator perimeter in length) to<br />
reduce the effects of frequency lock-in at low rotation rates. The basic idea is to reduce the crosscoupling<br />
between the two counter-propagating be<strong>am</strong>s by limiting the regions in the cavity where the<br />
two pulses overlap. Wax <strong>and</strong> Chodorow [1972] report an improvement in per<strong>for</strong>mance of two orders<br />
of magnitude through the use of intracavity phase modulation. Other techniques based on non-linear<br />
optics have been proposed, including an approach by Litton that applies an external magnetic field<br />
to the cavity to create a directionally dependent phase shift <strong>for</strong> biasing [Martin, 1986]. Yet another<br />
solution to the lock-in problem is to remove the lazing medium from the ring altogether, effectively<br />
<strong>for</strong>ming what is known as a passive ring resonator.
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