scholarly journals Space Point Target Ranging System Based on Laser Beam Triangulation

2020 ◽  
Vol 782 ◽  
pp. 032095
Author(s):  
Boyang Sun ◽  
Gang Liu ◽  
Zhao Xu ◽  
Shengwei Lv ◽  
Shuming Yao
Keyword(s):  
Laser Beam ◽  
Point Target ◽  
Target Ranging ◽  
Space Point

Design of highly sensitive space point target detection system

2018 ◽  
Vol 11 (1) ◽  
pp. 115-122 ◽  
Author(s):  
刘 明 LIU Ming ◽  
邓 军 DENG Jun ◽  
冯献飞 FENG Xian-fei ◽  
钱峰松 QIAN Feng-song
Keyword(s):  
Target Detection ◽  
Detection System ◽  
Point Target ◽  
Highly Sensitive ◽  
Space Point ◽  
Point Target Detection

The Method of Laser Beam Focusing on the Distant Dynamic Point Target

2015 ◽  
Author(s):  
V. S. Denkevich ◽  
A. N. Kleymenov ◽  
Ya. I. Malashko ◽  
A. V. Nazarenko ◽  
A. O. Skvortsov
Keyword(s):  
Laser Beam ◽  
Beam Focusing ◽  
Point Target

Research on Dispersion and Striation Characteristic of Satellite Photoelectric Imaging System for Space Point Target Imaging

2014 ◽  
Vol 51 (9) ◽  
pp. 091101
Author(s):  
吕建明 Lü Jianming ◽  
牛燕雄 Niu Yanxiong ◽  
刘海霞 Liu Haixia ◽  
张颖 Zhang Ying ◽  
许冰 Xu Bing ◽  
...  
Keyword(s):  
Imaging System ◽  
Point Target ◽  
Target Imaging ◽  
Space Point

Boresight error in the conical scan method of autoboresighting a laser beam on a specular point-target

1982 ◽  
Vol 21 (19) ◽  
pp. 3607 ◽  
Author(s):  
Perambur S. Neelakantaswamy ◽  
Arthur Rajaratram
Keyword(s):  
Laser Beam ◽  
Point Target ◽  
Conical Scan ◽  
Boresight Error

Two-photon excitation microscopy in cellular biophysics

1995 ◽  
Vol 53 ◽  
pp. 62-63
Author(s):  
David W. Piston ◽  
Brian D. Bennett ◽  
Robert G. Summers
Keyword(s):  
Confocal Microscopy ◽  
Laser Beam ◽  
Duty Cycle ◽  
Excited Electronic State ◽  
Input Power ◽  
Two Photon ◽  
Simultaneous Absorption ◽  
Photon Excitation ◽  
Very High ◽  
Two Photon Excitation

Two-photon excitation microscopy (TPEM) provides attractive advantages over confocal microscopy for three-dimensionally resolved fluorescence imaging and photochemistry. Two-photon excitation arises from the simultaneous absorption of two photons in a single quantitized event whose probability is proportional to the square of the instantaneous intensity. For example, two red photons can cause the transition to an excited electronic state normally reached by absorption in the ultraviolet. In practice, two-photon excitation is made possible by the very high local instantaneous intensity provided by a combination of diffraction-limited focusing of a single laser beam in the microscope and the temporal concentration of 100 femtosecond pulses generated by a mode-locked laser. Resultant peak excitation intensities are 106 times greater than the CW intensities used in confocal microscopy, but the pulse duty cycle of 10-5 maintains the average input power on the order of 10 mW, only slightly greater than the power normally used in confocal microscopy.

The atomic-force microscope and its future in biology

1993 ◽  
Vol 51 ◽  
pp. 704-705
Author(s):  
Jean-Paul Revel
Keyword(s):  
Silicon Nitride ◽  
Laser Beam ◽  
Atomic Force Microscope ◽  
Scanning Tunneling Microscope ◽  
Point Of View ◽  
Scanning Tunneling ◽  
Close Relative ◽  
Tunneling Microscope ◽  
Atomic Force ◽  
Sharp Point

The last few years have been marked by a series of remarkable developments in microscopy. Perhaps the most amazing of these is the growth of microscopies which use devices where the place of the lens has been taken by probes, which record information about the sample and display it in a spatial from the point of view of the context. From the point of view of the biologist one of the most promising of these microscopies without lenses is the scanned force microscope, aka atomic force microscope.This instrument was invented by Binnig, Quate and Gerber and is a close relative of the scanning tunneling microscope. Today's AFMs consist of a cantilever which bears a sharp point at its end. Often this is a silicon nitride pyramid, but there are many variations, the object of which is to make the tip sharper. A laser beam is directed at the back of the cantilever and is reflected into a split, or quadrant photodiode.

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