Presentation is loading. Please wait.

Presentation is loading. Please wait.

Anti-laser and Lidar By Mego Easley Jake Landess and Andrew Newberry.

Published byTatiana Bilbo Modified over 9 years ago

Similar presentations

Presentation on theme: "Anti-laser and Lidar By Mego Easley Jake Landess and Andrew Newberry."— Presentation transcript:

1 Anti-laser and Lidar By Mego Easley Jake Landess and Andrew Newberry

2 Anti-Laser FOuter unit Sensor circuit special infrared lens that focuses laser light onto the detection amplification Circuit admits only lidar It admits impulses that are equal to the laser impulses FOuter unit Sensor circuit special infrared lens that focuses laser light onto the detection amplification Circuit admits only lidar It admits impulses that are equal to the laser impulses

3 Anti-Laser Inner unit The Inner unit contains an audio visual and processing circuit In the center of the unit the processing unit recieves signals from the sensor circuit Inner unit The Inner unit contains an audio visual and processing circuit In the center of the unit the processing unit recieves signals from the sensor circuit

4 How Lidar Works FThe laser beam which is narrower then a radar beam, is how it can be used for heavy traffic FThe moment the trigger is activated, lidar starts, and in the next.5 seconds it takes 50 measurements and calculates speed FAlso the range of the lidar is decreased when the weather conditions are bad and the target area, and the licence plate reflection of the lidar is halved FThe laser beam which is narrower then a radar beam, is how it can be used for heavy traffic FThe moment the trigger is activated, lidar starts, and in the next.5 seconds it takes 50 measurements and calculates speed FAlso the range of the lidar is decreased when the weather conditions are bad and the target area, and the licence plate reflection of the lidar is halved

5 Specs. Of AntiLaser F85x22x40mm is the inner unit F50x20x50mm is the outer unit F904nm- laser wave length F10,5V-15V- power F300mA max. current consumption F85 dB speaker volume F1M laser class F85x22x40mm is the inner unit F50x20x50mm is the outer unit F904nm- laser wave length F10,5V-15V- power F300mA max. current consumption F85 dB speaker volume F1M laser class

6 Continued specs of Anti- Laser FLTI Marksman 20.20, Multilaser LTI UltraLyte, LR,100,100LR,200,200LR, COMPACT, LRB Multinova- Starlaser Robot-TrafficPatrol, V Sagem-Mester laser Stalker-Lz1 Laser Atlanta- Speedlaser,s,r,Stealth Mode Traffic Observer- LMS 291/221/04/05 FLTI Marksman 20.20, Multilaser LTI UltraLyte, LR,100,100LR,200,200LR, COMPACT, LRB Multinova- Starlaser Robot-TrafficPatrol, V Sagem-Mester laser Stalker-Lz1 Laser Atlanta- Speedlaser,s,r,Stealth Mode Traffic Observer- LMS 291/221/04/05

7 Types of Speed Detection Systems FRadar devices, loop technology, light beams, video systems(fixed and mobile), and finally Lidar

8 Lidar FLidar is Light detection and Ranging Lidar is a small laser that is focused on an object and then calculated in order to tell the speed an automobile is traveling at FLidar is Light detection and Ranging Lidar is a small laser that is focused on an object and then calculated in order to tell the speed an automobile is traveling at

9 Installation FThe outer unit of the Anti laser is put on the front of the vehicle the outer is made to withstand many harmful conditions FThe inner unit has to be put some were accesible and some where were you can turn it on and off very easily FThe outer unit of the Anti laser is put on the front of the vehicle the outer is made to withstand many harmful conditions FThe inner unit has to be put some were accesible and some where were you can turn it on and off very easily

10 Radar FRadar is an electronic tool which uses electromagnetic waves to detect and locate moving or fixed objects

11 Police Radar FUtilizes radio waves and the Doppler Effect FPolice Laser Radar(Lidar) utilizes light waves and the pulse principle FUtilizes radio waves and the Doppler Effect FPolice Laser Radar(Lidar) utilizes light waves and the pulse principle

12 Doppler Principle FStates that the measured frequency of a wave is relative to the motion between the source and the observer

13 How Radar Works FThe Radar Gun is used to send out radio waves of specific frequencies in a chosen direction FThe waves bounce off objects and return to the radar gun(when the waves reflect it is known as Doppler Shift) FThe radar gun computer then uses the frequency to calculate the speed FThe Radar Gun is used to send out radio waves of specific frequencies in a chosen direction FThe waves bounce off objects and return to the radar gun(when the waves reflect it is known as Doppler Shift) FThe radar gun computer then uses the frequency to calculate the speed

14 Radar Detectors FThe idea behind them, are that they look for radar “beams” and find them before they can return a strong enough reflection to “illuminate” you FRadars are essentially microwave radio receivers that make noise or flash lights when they sense an incoming signal on specific frequencies FThe idea behind them, are that they look for radar “beams” and find them before they can return a strong enough reflection to “illuminate” you FRadars are essentially microwave radio receivers that make noise or flash lights when they sense an incoming signal on specific frequencies

15 Radar Beam FThe radar antenna transmits the signal in a directional beam similar to the configuration of a flashlight beam FPolice traffic radar beam is conical in shape and continues outward indefinitely from the antenna until it is reflected, refracted, or absorbed FThe radar antenna transmits the signal in a directional beam similar to the configuration of a flashlight beam FPolice traffic radar beam is conical in shape and continues outward indefinitely from the antenna until it is reflected, refracted, or absorbed

16 The End

Download ppt "Anti-laser and Lidar By Mego Easley Jake Landess and Andrew Newberry."

Similar presentations

INTRODUCTION APPLICATION IN THE DRIVING SEAT THE DOCTOR WILL SEE WIRED WEARABLES DO NOT KEEP YOUR EYES ON ROAD ADAPTIVE CRUISE CONTROL(A.C.C.) WORKING.

INTRODUCTION APPLICATION IN THE DRIVING SEAT THE DOCTOR WILL SEE WIRED WEARABLES DO NOT KEEP YOUR EYES ON ROAD ADAPTIVE CRUISE CONTROL(A.C.C.) WORKING.
Mapping with the Electronic Spectrum

Mapping with the Electronic Spectrum
Hearing. How hearing works First, the ear gathers the compressional waves. Next, the ear amplifies the waves. In the ear, the amplified waves are converted.

Hearing. How hearing works First, the ear gathers the compressional waves. Next, the ear amplifies the waves. In the ear, the amplified waves are converted.
Section 2: The Nature of Light

Section 2: The Nature of Light
7. Radar Meteorology References Battan (1973) Atlas (1989)

7. Radar Meteorology References Battan (1973) Atlas (1989)
Today 1/27  HW: 1/27 Handout “Anti-Reflection Coating” due Thursday 1/30  Today: Reflections at Boundaries 27.3  Thin Film Interference 27.3  Labs.

Today 1/27  HW: 1/27 Handout “Anti-Reflection Coating” due Thursday 1/30  Today: Reflections at Boundaries 27.3  Thin Film Interference 27.3  Labs.
Forces and Motion Essential Vocabulary

Forces and Motion Essential Vocabulary
Lecture 12 Content LIDAR 4/15/2017 GEM 3366.

Lecture 12 Content LIDAR 4/15/2017 GEM 3366.
PS 1-7-08 Finish Light Color Uses of Electromagnetic spectrum.

PS Finish Light Color Uses of Electromagnetic spectrum.
Refraction Minimize t with respect to x dt/dx=0 using dL 1 /dx=x/L 1 =sin  1 and dL 2 /dx=(x-d)/L 2 = -sin  2 dt/dx=(n 1 sin  1 - n 2 sin  2 )/c =

Refraction Minimize t with respect to x dt/dx=0 using dL 1 /dx=x/L 1 =sin  1 and dL 2 /dx=(x-d)/L 2 = -sin  2 dt/dx=(n 1 sin  1 - n 2 sin  2 )/c =
Introduction to Remote Sensing The Electromagnetic (EM) Spectrum.

Introduction to Remote Sensing The Electromagnetic (EM) Spectrum.
DISTANCE DETECTION EE 594 - Consumer Optoelectronics Dave Vu March 17, 1999.

DISTANCE DETECTION EE Consumer Optoelectronics Dave Vu March 17, 1999.
Doppler Effect(1) Stationary source Stationary observer Moving source

Doppler Effect(1) Stationary source Stationary observer Moving source
Radar Many in a series of McGourty- Rideout Productions.

Radar Many in a series of McGourty- Rideout Productions.
Waves of the Electromagnetic Spectrum

Waves of the Electromagnetic Spectrum
MOBILE RADAR GUN TECHNOLOGY +. INTRODUCTION How it works Uses of our product Pricing Website.

MOBILE RADAR GUN TECHNOLOGY +. INTRODUCTION How it works Uses of our product Pricing Website.
Waves can also be reflective and refractive Waves can bounce off of something after striking it. That is a reflection. Sound and light waves can equally.

Waves can also be reflective and refractive Waves can bounce off of something after striking it. That is a reflection. Sound and light waves can equally.
Spring 2006UCSD: Physics 8; 20063 Examples of Electromagnetic Waves/Radiation Radio Waves (AM and FM radio waves andTV signals) Cell phone communication.

Spring 2006UCSD: Physics 8; Examples of Electromagnetic Waves/Radiation Radio Waves (AM and FM radio waves andTV signals) Cell phone communication.
Radar: Acronym for Radio Detection and Ranging

Radar: Acronym for Radio Detection and Ranging
Doppler Effect. Moving Source  Light moves equally in all directions from a source. Circular (or spherical) patternCircular (or spherical) pattern 

Doppler Effect. Moving Source  Light moves equally in all directions from a source. Circular (or spherical) patternCircular (or spherical) pattern 

Similar presentations

Ads by Google