Sensors and Methods for Mobile Robot Positioning

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32 Part I Sensors for Mobile Robot Positioning Outer pivot Wheel bearing Wheel Outer gimbal Inner pivot Inner gimbal Figure 2.1: Typical two-axis mechanical gyroscope configuration [Everett, 1995]. 2.1.2 Gyrocompasses The gyrocompass is a special configuration of the rate integrating gyroscope, employing a gravity reference to implement a north-seeking function that can be used as a true-north navigation reference. This phenomenon, first demonstrated in the early 1800s by Leon Foucault, was patented in Germany by Herman Anschutz-Kaempfe in 1903, and in the U.S. by Elmer Sperry in 1908 [Carter, 1966]. The U.S. and German navies had both introduced gyrocompasses into their fleets by 1911 [Martin, 1986]. The north-seeking capability of the gyrocompass is directly tied to the horizontal earth rate component measured by the horizontal axis. As mentioned earlier, when the gyro spin axis is oriented in a north-south direction, it is insensitive to the earth's rotation, and no tilting occurs. From this it follows that if tilting is observed, the spin axis is no longer aligned with the meridian. The direction and magnitude of the measured tilt are directly related to the direction and magnitude of the misalignment between the spin axis and true north. 2.1.3 Commercially Available Mechanical Gyroscopes Numerous mechanical gyroscopes are available on the market. Typically, these precision machined gyros can cost between $10,000 and $100,000. Lower cost mechanical gyros are usually of lesser quality in terms of drift rate and accuracy. Mechanical gyroscopes are rapidly being replaced by modern high-precision — and recently — low-cost fiber-optic gyroscopes. For this reason we will discuss only a few low-cost mechanical gyros, specifically those that may appeal to mobile robotics hobbyists.
Chapter 2: Heading Sensors 33 2.1.3.1 Futaba Model Helicopter Gyro The Futaba FP-G154 [FUTABA] is a lowcost low-accuracy mechanical rate gyro designed for use in radio-controlled model helicopters and model airplanes. The Futaba FP-G154 costs less than $150 and is available at hobby stores, for example [TOWER]. The unit comprises of the mechanical gyroscope (shown in Figure 2.2 with the cover removed) and a small control amplifier. Designed for weight-sensitive model helicopters, the system weighs only 102 grams (3.6 oz). Motor and amplifier run off a 5 V DC supply and consume only 120 mA. However, sensitivity and accuracy are orders of magnitude lower than “professional” Figure 2.2: The Futaba FP-G154 miniature mechanical gyroscope for radio-controlled helicopters. The unit costs less than $150 and weighs only 102 g (3.6 oz). mechanical gyroscopes. The drift of radio-control type gyroscopes is on the order of tens of degrees per minute. 2.1.3.2 Gyration, Inc. The GyroEngine made by Gyration, Inc. [GYRATION], Saratoga, CA, is a low-cost mechanical gyroscope that measures changes in rotation around two independent axes. One of the original applications for which the GyroEngine was designed is the GyroPoint, a three-dimensional pointing device for manipulating a cursor in three-dimensional computer graphics. The GyroEngine model GE9300-C has a typical drift rate of about 9(/min. It weighs only 40 grams (1.5 oz) and compares in size with that of a roll of 35 millimeter film (see Figure 2.3). The sensor can be powered with 5 to 15 VDC and draws only 65 Figure 2.3: The Gyration GyroEngine compares in size favorably with a roll of 35 mm film (courtesy Gyration, Inc.). to 85 mA during operation. The open collector outputs can be readily interfaced with digital circuits. A single GyroEngine unit costs $295. 2.2 Piezoelectric Gyroscopes Piezoelectric vibrating gyroscopes use Coriolis forces to measure rate of rotation. in one typical design three piezoelectric transducers are mounted on the three sides of a triangular prism. If one of the transducers is excited at the transducer's resonance frequency (in the Gyrostar it is 8 kHz),
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CHAPTER 5 ODOMETRY AND OTHER DEAD-R
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R e t r o r e f l e c t i v e m a r
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CHAPTER 8 MAP-BASED POSITIONING Map
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218 Appendices, References, Indexes
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220 Appendices, References, Indexes
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Systems-at-a-Glance Tables Odometry
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Systems-at-a-Glance Tables Global N
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Systems-at-a-Glance Tables Landmark
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REFERENCES 1. Abidi, M. and Chandra
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238 References 31. Boltinghouse, S.
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240 References MOBOT-IV.” Proceed
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242 References 90. Dahlin, T. and K
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244 References 120. Fisher, D., Hol
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246 References 156. Janet, J., Luo,
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252 References 249. Sanders, G.A.,
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254 References 278. Turpin, D.R., 1
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256 References 309. EATON - Eaton-K
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258 References 349. SPSi - Spatial
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262 Index AC ..............47, 59,
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