Where am I? Sensors and Methods for Mobile Robot Positioning

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124 Part I Sensors for Mobile Robot Positioning f(t) = f + at (4.7) 0 where a = constant t = elapsed time. f 2d/c This signal is reflected from a target and arrives at the receiver at time t + T. fo t 2d T = — (4.8) c where T = round-trip propagation time d = distance to target c = speed of light. Figure 4.34: The received frequency curve is shifted along the time axis relative to the reference frequency [Everett, 1995]. The received signal is compared with a reference signal taken directly from the transmitter. The received frequency curve will be displaced along the time axis relative to the reference frequency curve by an amount equal to the time required for wave propagation to the target and back. (There might also be a vertical displacement of the received waveform along the frequency axis, due to the Doppler effect.) These two frequencies when combined in the mixer produce a beat frequency F : b F = f(t) - f(T + t) = aT (4.9) b where a = constant. This beat frequency is measured and used to calculate the distance to the object: d F c b 4 F r F d (4.10) where d = range to target c = speed of light F = beat frequency b F = repetition (modulation) frequency r F = total FM frequency deviation. d Distance measurement is therefore directly proportional to the difference or beat frequency, and as accurate as the linearity of the frequency variation over the counting interval.
Chapter 4: Sensors for Map-Based Positioning 125 Advances in wavelength control of laser diodes now permit this radar ranging technique to be used with lasers. The frequency or wavelength of a laser diode can be shifted by varying its temperature. Consider an example where the wavelength of an 850-nanometer laser diode is shifted by 0.05 nanometers in four seconds: the corresponding frequency shift is 5.17 MHz per nanosecond. This laser beam, when reflected from a surface 1 meter away, would produce a beat frequency of 34.5 MHz. The linearity of the frequency shift controls the accuracy of the system; a frequency linearity of one part in 1000 yards yields an accuracy of 1 millimeter. The frequency-modulation approach has an advantage over the phase-shift-measurement technique in that a single distance measurement is not ambiguous. (Recall phase-shift systems must perform two or more measurements at different modulation frequencies to be unambiguous.) However, frequency modulation has several disadvantages associated with the required linearity and repeatability of the frequency ramp, as well as the coherence of the laser beam in optical systems. As a consequence, most commercially available FMCW ranging systems are radar-based, while laser devices tend to favor TOF and phase-detection methods. 4.3.1 Eaton VORAD Vehicle Detection and Driver Alert System VORAD Technologies [VORAD-1], in joint venture with [VORAD-2], has developed a commercial millimeter-wave FMCW Doppler radar system designed for use on board a motor vehicle [VORAD- 1]. The Vehicle Collision Warning System employs a 12.7×12.7-centimeter (5×5 in) antenna/transmitter-receiver package mounted on the front grill of a vehicle to monitor speed of and distance to other traffic or obstacles on the road (see Figure4.35). The flat etched-array antenna radiates approximately 0.5 mW of power at 24.725 GHz directly down the roadway in a narrow directional beam. A GUNN diode is used for the transmitter, while the receiver employs a balancedmixer detector [Woll, 1993]. Figure 4.35: The forward-looking antenna/transmitter/ receiver module is mounted on the front of the vehicle at a height between 50 and 125 cm, while an optional side antenna can be installed as shown for blind-spot protection. (Courtesy of VORAD-2).
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7KH8QLYHUVLW\RI0LFKLJDQ Where am I
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Acknowledgments This research was s
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6.4 Summary .......................
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INTRODUCTION Leonard and Durrant-Wh
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Part I Sensors for Mobile Robot Pos
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14 Part I Sensors for Mobile Robot
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CHAPTER 2 HEADING SENSORS Heading s
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174 Part II Systems and Methods for
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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 Beacon 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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248 References 187. Larsson, U., Ze
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250 References 220. Nolan, D.A., Bl
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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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260 References 380. MacKenzie, P. a
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262 Index AC ..............47, 59,
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264 Index Datums ..................
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266 Index glass ...................
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268 Index lateral-post ............
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270 Index NPN .....................
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272 Index signal ..... 17, 31, 38,
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274 Index Abidi ...................
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280 Index Video Index This CD-ROM c
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282 Index Paper 52 Paper 53 Paper 5
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