Optoelectronic sensor of longitudinal and angular displacements

Optoelectronic sensor of longitudinal and angular displacements

In the sensor a triangulation method of displacement measurement has been used. A method of sensor calibration using interferometric distance measurements has been elaborated. Linearity and resolution investigations have been performed for different parameter sets of sensor transmitting-receiving he...

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Дата:1999
Автори: Dlugaszek, A., Jabczynski, J., Janucki, J., Skrzeczanowski, W.
Формат: Стаття
Мова:English
Опубліковано: Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України 1999
Назва видання:Semiconductor Physics Quantum Electronics & Optoelectronics
Онлайн доступ:https://nasplib.isofts.kiev.ua/handle/123456789/119869
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Назва журналу:Digital Library of Periodicals of National Academy of Sciences of Ukraine
Цитувати:Optoelectronic sensor of longitudinal and angular displacements / A. Dlugaszek, J. Jabczynski, J. Janucki, W. Skrzeczanowski // Semiconductor Physics Quantum Electronics & Optoelectronics. — 1999. — Т. 2, № 3. — С. 71-73. — Бібліогр.: 5 назв. — англ.

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Digital Library of Periodicals of National Academy of Sciences of Ukraine
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spelling nasplib_isofts_kiev_ua-123456789-1198692025-02-09T09:53:42Z Optoelectronic sensor of longitudinal and angular displacements Dlugaszek, A. Jabczynski, J. Janucki, J. Skrzeczanowski, W. In the sensor a triangulation method of displacement measurement has been used. A method of sensor calibration using interferometric distance measurements has been elaborated. Linearity and resolution investigations have been performed for different parameter sets of sensor transmitting-receiving head. An accuracy of displacement measurements depends on parameters of a beam illuminating a surface being displaced, parameters of a position sensitive detector and on a signal-to-noise ratio of a signal analog processing block. Results of investigations of uncertainties of lathe slide shifts are also presented. 1999 Article Optoelectronic sensor of longitudinal and angular displacements / A. Dlugaszek, J. Jabczynski, J. Janucki, W. Skrzeczanowski // Semiconductor Physics Quantum Electronics & Optoelectronics. — 1999. — Т. 2, № 3. — С. 71-73. — Бібліогр.: 5 назв. — англ. 1560-8034 PACS 07.07.D, 42.79.P,Q https://nasplib.isofts.kiev.ua/handle/123456789/119869 en Semiconductor Physics Quantum Electronics & Optoelectronics application/pdf Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description In the sensor a triangulation method of displacement measurement has been used. A method of sensor calibration using interferometric distance measurements has been elaborated. Linearity and resolution investigations have been performed for different parameter sets of sensor transmitting-receiving head. An accuracy of displacement measurements depends on parameters of a beam illuminating a surface being displaced, parameters of a position sensitive detector and on a signal-to-noise ratio of a signal analog processing block. Results of investigations of uncertainties of lathe slide shifts are also presented.
format Article
author Dlugaszek, A.
Jabczynski, J.
Janucki, J.
Skrzeczanowski, W.
spellingShingle Dlugaszek, A.
Jabczynski, J.
Janucki, J.
Skrzeczanowski, W.
Optoelectronic sensor of longitudinal and angular displacements
Semiconductor Physics Quantum Electronics & Optoelectronics
author_facet Dlugaszek, A.
Jabczynski, J.
Janucki, J.
Skrzeczanowski, W.
author_sort Dlugaszek, A.
title Optoelectronic sensor of longitudinal and angular displacements
title_short Optoelectronic sensor of longitudinal and angular displacements
title_full Optoelectronic sensor of longitudinal and angular displacements
title_fullStr Optoelectronic sensor of longitudinal and angular displacements
title_full_unstemmed Optoelectronic sensor of longitudinal and angular displacements
title_sort optoelectronic sensor of longitudinal and angular displacements
publisher Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
publishDate 1999
url https://nasplib.isofts.kiev.ua/handle/123456789/119869
citation_txt Optoelectronic sensor of longitudinal and angular displacements / A. Dlugaszek, J. Jabczynski, J. Janucki, W. Skrzeczanowski // Semiconductor Physics Quantum Electronics & Optoelectronics. — 1999. — Т. 2, № 3. — С. 71-73. — Бібліогр.: 5 назв. — англ.
series Semiconductor Physics Quantum Electronics & Optoelectronics
work_keys_str_mv AT dlugaszeka optoelectronicsensoroflongitudinalandangulardisplacements
AT jabczynskij optoelectronicsensoroflongitudinalandangulardisplacements
AT januckij optoelectronicsensoroflongitudinalandangulardisplacements
AT skrzeczanowskiw optoelectronicsensoroflongitudinalandangulardisplacements
first_indexed 2025-11-25T12:22:41Z
last_indexed 2025-11-25T12:22:41Z
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fulltext 71© 1999, Institute of Semiconductor Physics, National Academy of Sciences of Ukraine Semiconductor Physics, Quantum Electronics & Optoelectronics. 1999. V. 2, N 3. P. 71-73. PACS 07.07.D, 42.79.P,Q Optoelectronic sensor of longitudinal and angular displacements A. Dlugaszek, J. Jabczynski, J. Janucki, W. Skrzeczanowski Institute of Optoelectronics, Military University of Technology, 2 Kaliskiego str. 00-908 Warsaw, POLAND, tel. (48 22) 6859678, fax (48 22) 6668950, e-mail: jabczy@wat.waw.pl, wskrzecz@wat.waw.pl Abstract. In the sensor a triangulation method of displacement measurement has been used. A method of sensor calibration using interferometric distance measurements has been elaborated. Linearity and resolution investigations have been performed for different parameter sets of sensor transmitting-receiv- ing head. An accuracy of displacement measurements depends on parameters of a beam illuminating a surface being displaced, parameters of a position sensitive detector and on a signal-to-noise ratio of a signal analog processing block. Results of investigations of uncertainties of lathe slide shifts are also presented. Keywords: optoelectronic sensor, position-sensitive detector, longitudial displacement, angular dis- placement Paper received 08.09.99; revised manuscript received 30.09.99; accepted for publication 04.10.99. 1. Introduction Measurements of small angular deviations are carried out using interferometry methods as a rule [1]. Such systems (see, for example, [2]) allow displacement measurements only in one plane with 1 µrad accuracy. These measure- ments can be performed also using «geometrical» method, consisting in measurements of X, Y positions of point im- age in a lens focal plane next divided by focal length f. A triangulation method is one of contactless methods of displacement measurements [3]. In this method a moving object is illuminated by light beam at a certain angle to ob- servation axis. An image of a light spot illuminating mov- ing surface of an object changes its position at position sen- sitive detector (PSD). A linearized, approximate depend- ence between displacement Z and a position of a spot im- age at a detector XA is given by (1): αsin 00 0 ⋅ − ⋅≅ fZ f ZX A , (1) where: Z is a value of an object displacement from its initial position Z0, α is the angle between light beam illuminating an object and observation object, f0 is a focal length of an optical system of a receiving PSD part. A range of displacement measurement depends on a size of PSD photosensitive area and geometric parameters of optical systems of transmitting and receiving parts of a sen- sor. The range of linearity of dependence (1) is determined by a value of an angle α as well as by readout errors of a position of spot image on PSD surface (nonlinearity of de- tector characteristics). Next a resolution of displacement measurement depends on signal-to-noise ratio of a signal in a receiving system of a sensor and on resolution of readout system of output electrical signal. 2. Principle of operation of monolithic PSD detector A PSD detector used in a laboratory model is based on monolithic silicon p-i-n photodiode (Fig.1). Upper layer of a doped semiconductor has two deposited readout electrodes. A polarising electrode is deposited on a bottom layer. Light scattered on object surface is collected by optical system and then incidences on detector surface. In the photodiode i layer a conversion of light radiation into electric current flowing from polarising electrode to readout electrodes occurs.Owing to resistance homogeneity of upper layer of a detector, the values of photocurrents reaching readout elec- trodes are inversely proportional to a distance between place of radiation incidencing on detector surface and a readout electrode (Fig.1). That is why a position of a spot image on PSD surface is given by dependence (2) like that in [2]: ( )21,2 IIYLX nA ⋅= , (2) A. Dlugaszek et al.: Optoelectronic sensor of longitudinal and angular displacements 72 SQO, 2(3), 1999 where: XA is a spot image position on PSD surface, I1 and I2 are photocurrents at first and second readout electrodes, re- spectively, L is a length of photosensitive surface of PSD de- tector, Yn is a normalising function given by dependence (3): ( ) xy xy yxYn + −=, . (3) Readout resolution of a position of a light spot on detector surface depends on PSD intrinsic noise (thermal noise, shot noise) and on optical noise reaching PSD surface. In order to improve sensor resolution one can use modulation of intensity of a beam illuminating moving object and synchronous reception of radiation scattered on its surface. Monolithic PSD detectors have many advantages in comparison with such discrete PSD’s as CCD [4] or photodiode linear detectors. These are as follows: § analog, continuous measurement of a position of radiation beam illuminating the surface, § resolution of position readout, § high speed of pulse response, § simple system of electronic processing of a signal. 3. Sensor calibration A calibration of an angular deviation sensor is performed if a value of a coefficient defining a connection between volt- age signals from a signal analog processor and angular de- viations of radiation beam illuminating PSD surface is found. Measurements have been carried out using laboratory set- up shown in Fig.2. He-Ne laser with a UPF beam expander is a radiation source in this set-up.Light beam deviated by means of mirror M is splitted into two beams in a beam splitter DW. One beam is directed to PSD-2D detection path, while the second one is directed into LBA 100A system for registration of spatial distributions [5]. The use of UFP al- lows one to achieve a high spatial stability of a light beam. Measurements of spatial stability showed that determining of a beam center position with 1 µm accuracy is possible, which for focal length f = 300 mm gives 3 mrad. Calibrations were based on simultaneous measurements of angular deviations in different directions using LBA 100A system and changes of output voltage signals from the APS processor of the sensor. Calibration curve is shown in Fig.3. Correlation coefficient r = 0.8 between LBA measurements and APS voltage signals was found. Mean square deviation of nonlinearity was about 8%.Nonlinearity of a calibration curve, shown in Fig.3, defined as a deviation from the straight line approximating the dependence amounts in this case is 3.4%. The 0.5 µm resolution for displacement meas- urement has been achieved for the measurement range ∆Z. It depends on geometrical parameters of a sensor system, ratio of a light spot diameter to sensor size, and on light and electronic noise. In the case of large displacement range, a measurement nonlinearity (Fig.4) is much higher than in former case and amounts to 24%. It is caused by nonlinearity of the method itself (system responsivity varies according to displacement change from 0.02 up to 0.06 V/mm). 4. Measurements of angular displacements Preliminary measurements of angular displacements have been carried out using arrangement shown in Fig.5. Slide shifts were measured using HP 5526A interferometer. Po- larizing beam splitter of the interferometer was attached in a lathe chuck, while prism mirror together with transmit- ting head GN of the sensor were fasten to the lathe slide. The TD receiving system of a sensor was set on the lathe frame. The stand in Fig.5 allows one to simultaneously measu linear- ity and angular displacements of lathe slide shift. Fig.1. A structure of monolithic PSD detector Fig.2. A scheme of a laboratory stand for sensor calibration. p layer i layer n layer hν Anode 2 Cathode Anode 1 I 2 I 1 UFP P F He-Ne Laser CCD-2D LBA Monitor f1 f 2DW PSD-2D APS U x U y Dq M Fig.3. Results of sensor calibration. 2.5 1.5 0.5 focal length f [mm] = 62 sensitivity [mrad/V] = 6.15 measurement error [%] = 8 3 2 1 0 0 0.1 0.2 0.3 0.4 0.5 Voltage, V A ng le , m ra d focal length f, mm = 62 sensitivity, mrad/V = 6.15 measurement error, % = 8 A. Dlugaszek et al.: Optoelectronic sensor of longitudinal and angular displacements 73SQO, 2(3), 1999 About 2 µrad spatial stability of GN beam was found. Both the spatial stability of GN beam and APS resolution effect on the total uncertainty of an angular deviation meas- urement, which amounted to about 10 µrad. Measurement of linear slide shift makes a simultaneous calibration of lon- gitudinal lathe shift scale possible. Uncertainty of this cali- bration is 1µm. Results of angular deviation measurements are shown in Fig.6. 50 0 40 0 40 0 40 0 30 0 20 0 10 0 0 Z, m m X , mrad s Y , m r a d g 0.12 0.08 0.04 0 -0.04 -0.08 -0.12 Fig.6. Diagram of angular deviations Yg versus shift Z. Fig.5. Scheme of a stand for measurements of uncertainties of TUM 25A lathe slide shifts. -250 -200 -150 -100 -50 0 50 100 150 200 250 Z, mm Y , V 10 8 6 4 2 0 -2 -4 -6 -8 -10 Fig.4. Calibration curve F = f (Z) for the case of large displacement range. Conclusions A concept of the sensor of angular deviations was tested in laboratory and tool-room conditions. It seems, that the pre- sented sensor fulfils operational requirements for industrial control instruments. Changes of a focal length in a receiv- ing system of the sensor enable to have different measure- ment ranges of angular deviations in the investigated ob- ject. A high influence of optical noise on measurement reso- lution is a main disadvantage of the presented version of the sensor. Modulation of GN radiation and synchronous de- tection of optical signal used for reduction of optical noise should be of destination solution. Application of computer for statistical analysis in real time should ensure further im- provement in sensor abilities. References 1. K.Holejko, «Interferencyjne metody pomiaru przemieszczen i kata», V Krajowa Szkola Optoelektroniki, Waplewo, 1991, «Metrologia Laserowa», (in Polish), part. II, pp.53-74 2. Hewlett-Packard Co, «Laser Measurement System 5526A» 3. M.Buzinski, A.Levine, W.H.Stevenson, «Laser triangulation range sen- sors: A study of performance limitations», J.of Las. Appl., pp. 29-36, 1992 4. Hamamatsu Technical Data, «Large Area PSD Series», 1993 5. «Laser Beam Analyzer LBA 100A», Operator�s Manual

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