Home> Industry Information> laser sensor principle and application Overview

laser sensor principle and application Overview

July 25, 2018

Light and laser lasers were among the most significant scientific and technological achievements of the 1960s. Its rapid development has been widely used in defense, production, medical and non-electrical measurement. Unlike ordinary light, lasers need to be produced by lasers. The working substance of the laser, under normal conditions, most of the atoms are in a stable low energy level E1. Under the action of external light of appropriate frequency, the atomic absorption photon energy at the low energy level is excited and transitions to the high energy level E2. The photon energy E=E2-E1=hv, where h is the Planck constant and v is the photon frequency. Conversely, under the induction of light of frequency v, atoms at level E2 will transition to a lower energy level to release energy and emit light, called stimulated radiation. The laser firstly makes the atom of the working substance abnormally at a high energy level (ie, the population number is reversed), so that the stimulated radiation process is dominant, so that the induced light of the frequency v is enhanced and can pass through the parallel mirror. The formation of avalanche-type amplification produces strong stimulated radiation, referred to as laser.

The laser has three important characteristics:

1 high directionality (ie high directionality, low light velocity divergence angle), the laser beam extends over a few kilometers, but only a few centimeters;

2 high monochromaticity, the frequency width of the laser is 10 times smaller than ordinary light;

3 high brightness, using laser beam convergence can produce temperatures up to several million degrees.

Lasers can be divided into four types according to the working substance:

1 Solid-state laser: Its working substance is solid. Commonly used are ruby lasers, ytterbium-doped yttrium aluminum garnet lasers (ie, YAG lasers), and neodymium glass lasers. Their structure is roughly the same, characterized by small and sturdy, high power, and the neodymium glass laser is the device with the highest pulse output power, which has reached tens of megawatts.

2 gas laser: its working substance is gas. Various gas atoms, ions, metal vapors, and gas molecular lasers are available. Commonly used are carbon dioxide lasers, helium neon lasers and carbon monoxide lasers, which are shaped like ordinary discharge tubes and are characterized by stable output, good monochromaticity and long life, but low power and low conversion efficiency.

3 liquid laser: It can be divided into chelate laser, inorganic liquid laser and organic dye laser. The most important one is organic dye laser. Its biggest feature is that the wavelength is continuously adjustable.

4 semiconductor laser: It is a younger type of laser, of which the more mature is a gallium arsenide laser. It is characterized by high efficiency, small size, light weight and simple structure. It is suitable for carrying on airplanes, warships, tanks and infantry. It can be made into a range finder and a sight. However, the output power is small, the orientation is poor, and the ambient temperature is greatly affected.

laser sensor application

Non-contact long-distance measurement can be achieved by using the high directivity, high monochromaticity and high brightness of the laser. Laser sensors are often used for measuring physical quantities such as length, distance, vibration, speed, and azimuth. They can also be used for flaw detection and monitoring of atmospheric pollutants.

Laser length measurement: Precision measurement length is one of the key technologies in the precision machinery manufacturing industry and optical processing industry. Modern length measurement is mostly carried out by using the interference phenomenon of light waves, and the accuracy mainly depends on the monochromaticity of light. The laser is the ideal light source, which is 100,000 times purer than the best single-color light source (氪-86 lamp). Therefore, the laser length measuring range is large and the precision is high. It is known from the optical principle that the relationship between the maximum measurable length L of the monochromatic light and the wavelength λ and the line width δ is L = λ / δ. With a 氪-86 lamp, the maximum length can be measured to be 38.5 cm. For longer objects, segmentation measurement is required to reduce the accuracy. If a helium gas laser is used, it can measure up to several tens of kilometers. It is generally measured within a few meters and has an accuracy of 0.1 micron.

Laser ranging: Its principle is the same as that of radio radar. After the laser is aimed at the target, it is measured by its round-trip time, and then multiplied by the speed of light to get the round-trip distance. Due to the high directionality, high monochromaticity and high power of the laser, these are critical for measuring the distance, determining the target orientation, improving the signal-to-noise ratio of the receiving system, and ensuring the measurement accuracy. Therefore, the laser range finder More and more attention is being paid. The laser radar developed on the basis of laser range finder can not only measure distance, but also measure target azimuth, transport speed and acceleration. It has been successfully used for satellite ranging and tracking, such as laser using ruby laser. Radar, the range of ranging is 500-2000 km, and the error is only a few meters. Ruby lasers, neodymium glass lasers, carbon dioxide lasers, and gallium arsenide lasers are often used as light sources for laser range finder.

Laser vibration measurement: It measures the vibration velocity of an object based on the Doppler principle. The Doppler principle means that if the wave source or the observer of the received wave moves relative to the medium of the propagating wave, the frequency measured by the observer depends not only on the vibration frequency emitted by the wave source but also on the motion of the wave source or observer. The size and direction of the speed. The difference between the measured frequency and the frequency of the wave source is called the Doppler shift. When the vibration direction coincides with the direction, the frequency is shifted by fd=v/λ, where v is the vibration speed and λ is the wavelength. In the laser Doppler vibration velocity measuring instrument, fd = 2v / λ due to the round trip of light. The vibrometer converts the vibration of the object into a corresponding Doppler shift by the optical part during measurement, and the frequency shift is converted into an electrical signal by the photodetector, and then processed by the circuit part and sent to the appropriate The Puller signal processor converts the Doppler shift signal into an electrical signal corresponding to the vibration speed and finally records it on the magnetic tape. This vibrometer uses a HeNe laser with a wavelength of 6328 angstroms (┱), optical frequency modulation with an acousto-optic modulator, and a quartz crystal oscillator plus a power amplifier circuit as a driving source for the acousto-optic modulator, using a photomultiplier tube. Photoelectric detection is performed, and the frequency tracker is used to process the Doppler signal. The utility model has the advantages of convenient use, no need of a fixed reference frame, no influence on the vibration of the object itself, wide measurement frequency range, high precision and large dynamic range. The disadvantage is that the measurement process is greatly affected by other stray light.

Laser speed measurement: It is also a laser speed measurement method based on the principle of the Doppler. The laser Doppler flow meter (see laser flow meter) is used to measure wind tunnel air velocity, rocket fuel velocity, and aircraft jet. Air flow rate, atmospheric wind speed, and particle size and convergence rate in chemical reactions.

The above is the laser sensor principle and application Overview we have listed for you. You can submit the following form to obtain more industry information we provide for you.

You can visit our website or contact us, and we will provide the latest consultation and solutions

Share to:

Send Inquiry

Home> Industry Information> laser sensor principle and application Overview
We will contact you immediately

Fill in more information so that we can get in touch with you faster

Privacy statement: Your privacy is very important to Us. Our company promises not to disclose your personal information to any external company with out your explicit permission.

Send