LIDAR traffic enforcement

Lidar has a wide a range of applications; one use is in traffic enforcement and in particular speed limit enforcement, gradually replacing radar after 2000.[1] Current devices are designed to automate the entire process of speed detection, vehicle identification, driver identification and evidentiary documentation.[2]

Police officer operating a hand-held lidar speed detection device.

Etymology

Lidar is a portmanteau of 'light' and 'radar',[3] and an acronym for 'light detection and ranging'[4] or 'light (laser) imaging, detection and ranging'.[4] Unlike 'radar' ('radio detection and ranging') which is now regarded as a word,[5] not an acronym, there is no consensus on capitalisation,[6] however 'lidar' is in use, for example by The New York Times.[7] A use of the acronym occurred in 1953[8] and of the portmanteau in 1962.[3]

History

Lidar was used in the 1930's,[9][10][11][12] further development occurred after the invention of the laser in 1960,[13] from 1964 NASA has used lidar to map the earth and planets.[14] Jeremy Dunn (Laser Technology Inc.) developed a police lidar device in 1989,[15] and in 2004 10% of U.S. sales of traffic enforcement devices were lidar rising to 30% in 2006,[1] given the advantages of lidar it appears likely that the majority of current sales are lidar, although sophisticated radar units are still being sold.[16]

Current units combine five operations; speed detection; operator viewing, even under adverse conditions; imaging synchronised with speed detection; acquisition of court ready evidence; downloading of evidence to an external device. They can operate in automatic mode either attended or unattended.[17]

Advantages of lidar over radar

Radar has wide signal beam divergence,[15] so that an individual vehicle cannot be targeted, requiring significant operator skill, training and certification in order to visually estimate speed so as to locate an offender in a traffic stream, and offenders may use the defence that some other vehicle was offending. Radar will register the speed of any object in its field, for example a tree swaying or an airplane passing overhead.[1]

Lidar has a narrow beam, and easily targets an individual vehicle, thereby eliminating the need for visual estimation,[15][1] and records an image of the license plate at the same instant as recording the speed violation. Speed estimation takes less than half a second which together with the narrow, targeted beam results in offending vehicles having little warning even when using an evasion device. Lidar can measure the distance between vehicles to detect 'too close' (tailgating) infringements. The speed of a vehicle in the shadow of another vehicle cannot be measured

Lidar specifications

The US Department of Transportation National Highway Traffic Safety Administration (NHTSA) has issued specifications for lidar devices,[18] a conforming products list,[19] and guidelines regarding implementation of traffic enforcement.[20]

A typical NHTSA approved[19] device weighs less than two kilogram, is battery powered, has speed detection accuracy +2 kmh and -3 kmh, distance accuracy +- 0.3 metres at 90 metres, and minimum range 300 metres. Devices must be capable of meeting these accuracy standards while exposed to ambient temperatures between -30C and 60C, relative humidity of 90% at 37C and normal urban road ambient electromagnetic radiation. The range of speeds required to be accurately detected is 16 kmh to 320 kmh. Speeding violations are required to be documented by the device with a recorded image showing license plate, location, speed, date, time and operator identification, some units identify the driver by image and record the direction of travel.[2] The light emitted is required to be in the infrared range, meet eye safety standards, and have pulse repetition less than one kHz with beam divergence less than 5 milliradian.

Registration plates

Vehicle registration plates are an important part of traffic enforcement and in most jurisdictions the government holds a monopoly on the their manufacture, although this may be contracted out. Normally it is illegal for private citizens to modify, make and affix their own plates, as this is equivalent to forging an official document. California plates are required to be 15.24 cm in height and 30.48 cm in width, a usual standard, and have a reflective surface that is particularly sensitive to infrared light,[21] able to be imaged at night, enable Automatic License Plate Recognition, and have tamper-resistant markings.

Some jurisdictions do not require a front plate and many do not require certain vehicles such as motorcycles to have one. Police have preferred to detect from the front, enabling the offender to be waved over and avoiding pursuit. However the ability to detect, image and document violation in one operation reduces the need for pursuit, the offender can be sent the citation by post.

Evasion

A number of jurisdictions prohibit any methods to thwart speed limit enforcement, and lidar manufacturers endeavour to stay ahead of detection avoidance measures.

Current lidar devices have a horizontal beam width of one metre at 300 metres, compared to the registration plate width of 30 cm, ensuring that little of the signal is scattered to following vehicles. Detecting the police signal in advance is difficult as the tight beam, short signal duration and expert targeting of individual vehicles ensures little scatter of the police signal from advance targeted vehicles. Modifying the vehicle to deflect, absorb or jumble the signal is likely to be ineffective as it is the registration plate that is targeted. Modifying the registration plate is easily detected and is illegal. Returning a false separate signal will be detected by current police lidar models and may be illegal. These considerations have not stopped a proliferation of evasion devices in the market.

How it works

A typical NHTSA approved[19] lidar device emits 30 ns pulses of laser light with wavelength 905 nm and 50 milliwatts of power with 3 milliradian beam divergence. The time for this light to reach a vehicle and reflect back is measured, hence estimating the distance to the vehicle. Visible light has wavelength in the range 400 nm to 700 nm and the low power ensures no ocular damage occurs. Light travels approximately 30 cm per ns so each pulse has a length of about nine metres. At a target distance of 300 metres the light pulses take 2,000 ns to complete the round trip. The time interval between pulses is no less than one million ns, providing time to make a distance estimation from each pulse. Up to several hundred pulse readings are taken over a period less than half a second and used to estimate the change in distance over time, thereby estimating vehicle speed. Returning light is filtered to exclude light not in the wavelength range 899 nm to 909 nm. An internal proprietary algorithm rejects inaccurate readings; detection avoidance methods usually attempt to overload the filter and persuade the error rejection algorithm to incorrectly reject a reading.

Operation

An expert operator will use the viewing capability to select a likely offender prior to speed detection, this has the advantage that minimum signal is scattered to warn following vehicles equipped with lidar signal detection devices, this is not so important on sparsely trafficked roads and a lower capability lidar device may be used. Once a likely offender is detected and the registration plate targeted the operator triggers speed detection which includes acquisition of evidence, an audible tone indicates a good return signal. To produce an accurate reading the operator must focus the pulse on a single point for the duration of the read. At long range this is accomplished through the use of a stationary tripod to steady the aim. For speed detection any part of the vehicle may be targeted, although the registration plate is highly preferred.

Limitations

Normal weather conditions have negligible impact on device performance but may impede operator ability to target a vehicle, this includes occasions when the sun is directly behind the target vehicle, nighttime, or when the device is used within a stationary vehicle with a soiled windshield, in which case the signal might be scattered. Heavy weather may reduce the range of the device and in particular heavy fog will render it unusable.

When used within a moving vehicle the device measures the relative speed of the police and target vehicle, police are required to follow the offending vehicle for 200 metres and have a certified speedometer, largely negating advantages of the device.

Like radar, lidar is subject to cosine error effect.

Sweeping the device while taking a reading, so that, particularly at long range where angular separation between targets is slight, returning pulses from more than one target create a false reading. Sweeping along the side of a vehicle may also cause false readings.

A false reading is produced when the pulse reflects off for example a wing mirror, hits a stationary reflective object and then returns to reflect off the mirror a second time.

These errors are largely eliminated when current devices are expertly used.

Use in court

United States

In 2008, the D.C. Superior Court upheld the admissibility of lidar evidence in its jurisdiction. In addition to expert testimony, the court noted that it factored scientific publications into its decision:

The Court conducted an extensive four-day Frye [Daubert] hearing... [in which it] considered such issues as the basic science of laser technology, the technical methodology of, and theoretical challenges to, the reliability of radar guns... including the possibility of other “pulses” in the vicinity of use, difficulties in target identification, possible errors caused by vehicle license plates, windshield glass, shape, and color, and potential malfunction of the device. The Court also took judicial notice of at least six scientific publications on the subject in various journals of interest, together with two police-related studies in Florida, one New Jersey [study], and one independent study in Florida on this and similar radar devices, all of which met the standards set forth by [the] National Highway Safety Administration...

The court also noted that not a single court had conducted full-blown hearings on the issue that found LiDAR unreliable, while more than a dozen jurisdictions had decided that lidar is reliable.[22]

==References==

  1. 1 2 3 4 "LIDAR: The Speed Enforcement Weapon of Choice".
  2. 1 2 "Stalker LidarCam".
  3. 1 2 Ring, James (1963). "The Laser in Astronomy". New Scientist: pp. 672–673.
  4. 1 2 "Light Detection and Ranging". Ngs.noaa.gov. 2011-04-15. Retrieved 2016-02-22.
  5. Oxford English Dictionary. 2013. pp. entry for 'radar'.
  6. Oxford English Dictionary. 2013. pp. Entry for "lidar".
  7. "The Dream Life of Driverless Cars".
  8. Middleton & Spilhaus, E.K. & A.F. (1953). Meteorological Instruments. University of Toronto Press.
  9. Synge, E.H. (1930). "A method of investigating the higher atmosphere". Phill. Mag. 9: 1014–20.
  10. Tuve, Johnson & Wolf, M.A., E.A & O.R. (1935). "A new experimental method for study of the upper atmosphere". Terr. Mag. 40: 452.
  11. Hulbert, E.O. (1937). "Observations of a searchlight beam to an altitude of 28 kilometres". J Opt. Soc. Am. 27: 377.
  12. Johnson, Meyer & Hopkins, E.A., R.C. & R.E. (1939). "The measurement of light scattered by the upper atmosphere". J. Optical Soc. Amer. 29: 512–517.
  13. Maiman, T.H. (1960). "Optical maser action in ruby.". British Communications & Electronics: 674–76.
  14. "NASA's Space Lidar Measurements of the Earth and Planets" (PDF).
  15. 1 2 3 "Difference Between Radar and Lidar Explained".
  16. "Stalker Phodar".
  17. "LaserTech TruCam".
  18. "NHTSA lidar specifications" (PDF).
  19. 1 2 3 "NHTSA conforming product list" (PDF).
  20. "NHTSA traffic enforcement guidelines" (PDF).
  21. "Reflective License Plates Technology".
  22. "Admitting lidar evidence in Texas" (PDF).
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