MD1186Z - Method for identifying thin films of petroleum products according to their photoluminescence spectrum at a distance - Google Patents

Abstract

The invention relates to interferometry and can be used in environment-tracking systems for detection of petroleum product-contamination of water surfaces.The method, according to the invention, comprises the illumination with optical radiation causing photoluminescence of the object under study, which is on the water surface, from a remote distance by simultaneously recording a series of images of the photoluminescence region of the object with a digital camera through a system of narrow-band interference filters. Upon digital image processing, the photoluminescence signal caused by optical radiation is separated from the total luminous background reflected from the object, and the film of petroleum products is identified by comparing the obtained photoluminescence spectrum of the object under study with the standard photoluminescence spectrum of petroleum products.

Description

The invention relates to interferometry and can be used in environmental monitoring systems to detect oil pollution of aquatic surfaces.

A method of identifying petroleum products at long distances is known, which is based on obtaining their photoluminescence spectrum using a monochromator. In this method, the petroleum product spot is illuminated with a laser beam with a wavelength of 532 nm, as a result of which the photoluminescence phenomenon is observed. To visualize the photoluminescence, the signal reflected from the studied object is passed through a linear polarizer. The laser beam is linearly polarized, and for the angle of the linear polarizer β=90°, the laser radiation is passed through a tourmaline plate. Thus, after the reflected signal passes through the polarizer, only the photoluminescence of the petroleum product is observed, and the laser radiation with a wavelength of 532 nm is completely cut off by it. Then, the photoluminescence signal is passed through a monochromator, and the spectral distribution of the photoluminescence of the tested petroleum product is measured. According to the luminescence spectrum, petroleum products can be differentiated from other objects on water surfaces [1].

The disadvantage of this method is that the monochromator receives both the photoluminescence signal from the surface of the oil film reflected from the laser beam illumination and the one reflected from the sun, which creates an additional background signal. The proposed method does not allow separating the background signal from the laser photoluminescence signal. At the same time, in the case of contact of the oil product with other substances or objects, for example, small algae or marine organisms, the photoluminescence signal of oil product stains can be distorted by additional luminescence of organic substances. Also, this method does not allow separating the photoluminescence signal of oil products from the total signal, which reaches the monochromator.

The problem that the invention solves consists in increasing the accuracy of identifying thin films of petroleum products from long distances.

The method of identifying thin films of petroleum products according to their photoluminescence spectrum at a distance, according to the invention, eliminates the disadvantages mentioned above by including the illumination with optical radiation causing photoluminescence of the studied object, which is on the water surface, from a remote distance with the simultaneous recording of a series of images of the photoluminescence domain of the object using a digital camera through a system of narrow-band interference filters, at the same time, during digital processing of the images, the photoluminescence signal, caused by the illumination with optical radiation, is separated from the light background fully reflected from the object, and the petroleum product film is identified by comparing the obtained photoluminescence spectrum of the studied object with the standard photoluminescence spectrum of petroleum products.

The technical result of the invention consists in increasing the accuracy of identifying petroleum products from long distances.

The invention is explained by the drawings in Fig. 1-7, which represent:

- Fig. 1, diagram of the system for implementing the method for identifying thin films of petroleum products according to their remote photoluminescence spectrum (a), the image of the photoluminescence domain recorded through one of the narrow-band interference filters (b) and the image of the background signal reflected by the water surface, adjacent to the photoluminescence domain of the studied object (c);

- Fig. 2, image of 1 ml of engine oil deposited on the water surface (a) and image of the engine oil stain, spread out for 25 min (b);

- Fig. 3, an image of the engine oil stain illuminated with the integral background light and a discrete set of images of the stain and its photoluminescence spectrum taken using the system of interference filters with different wavelengths;

- Fig. 4, spectral dependence of the optical transparency of narrow-band interference filters;

- Fig. 5, spectral dependence of the transmission of a filter with maximum transmission at the wavelength of 546 nm normal to 1;

- Fig. 6, dependence of the brightness of the recorded images on the intensity of the incident radiation for the set of filters used;

- Fig. 7, spectral dependence of the photoluminescence intensity of the film on the aquatic surface obtained using the digital camera (dashed line) and the dependence obtained using the monochromator (solid line).

The method of identifying thin films of petroleum products according to their photoluminescence spectrum at a distance (see Fig. 1a) consists in the fact that the studied object 1 together with the background illumination 2, which imitates solar illumination, is illuminated with laser light 3, which causes photoluminescence of the film of petroleum products. At the same time, the light signals reflected from the studied object 1 and its photoluminescence spectrum 4 travel the distance L to the objective of the telescopic system 5, then are passed through the system of narrow-band interference filters 6 and recorded on the matrix of the digital camera 7. The image of the photoluminescence field recorded through one of the narrow-band interference filters 6 is transferred to the computer, where the photoluminescence intensity is determined in conventional units in the RGB system (Fig. 1b). The intensity of the background radiation is determined by the signal reflected from the surface of the layer adjacent to the photoluminescence domain of the studied object 1 (Fig. 1c). It is possible to select any portion or region of the background photoluminescence radiation, in places on the water surface where the signal is not distorted by the presence of other bodies.

Example

1 ml of engine oil was deposited on the water surface (Fig. 2a). Within 25 min the oil slick spread over the water surface to a diameter of approximately 12 cm (Fig. 2b). The calculated thickness of the oil slick is approximately 120 µm. The thin film of engine oil is illuminated with laser radiation 3 (Fig. 1) with a wavelength of 447 nm, which causes the engine oil to luminescence (Fig. 2b).

When identifying oil spills on open water surfaces under real conditions, the illumination of the object under study 1 can range from 1000 lx at sunrise to 100,000 lx at noon at maximum atmospheric transparency. The total light reflected from the surface of the engine oil can influence the accuracy of photoluminescence spectra measurements.

To simulate the conditions as realistically as possible, the thin film of engine oil was illuminated with a background light with an illumination of 75000 lx. In Fig. 3 (first frame) the image of the surface of the oil film with a thickness of approximately 120 µm illuminated with a background light of 75000 lx and a laser beam with λ=447 nm (P=60 mW) is presented, recorded by an optical installation from a distance of 15 m. Subsequently, the image of the studied object 1 and the photoluminescence spectrum are recorded by the digital camera matrix 7 as RAW files upon successive change of the narrow-band interference filters 6 (Fig. 6). The spectral dependence of the optical transparency of the narrow-band interference filters 6 normal to 1 is shown in Fig. 4. Each filter 6 is transparent in a narrow spectral range near the following wavelengths: 458 nm, 470 nm, 482 nm, 498 nm, 516 nm, 529 nm, 546 nm, 562 nm, 578 nm, 600 nm, 614 nm, 634 nm, 648 nm, 660 nm, 674 nm, 690 nm. As an example, in Fig. 5 the spectral dependence of the transmission of the narrow-band interference filter 6 with the transmission maximum at the wavelength of 546 nm normal to 1 is shown. As a result, a discrete set of images of the object 1 and its photoluminescence spectrum was obtained. As an example, in Fig. 3 shows the images of the photoluminescence spectra of the thin film of engine oil obtained from a distance of 15 m. Computer processing of RAW files allows to determine the brightness of the image in arbitrary units (from 0 to 255) separately for each of the channels of the RGB system. For images obtained using 458...498 nm filters, the brightness is determined according to the Blue channel, for 516...562 nm filters - according to the Green channel, and for 578...690 nm filters - according to the Red channel. To build the spectral dependence of the photoluminescence of the oil film, it is necessary to perform the gradation of the telescopic system 5 - the interference filters 6 - the matrix of the digital camera 7. The need for gradation is stipulated by the nonlinear spectral characteristic of the spectral sensitivity of digital cameras 7. As an example in fig. 6 shows the dependence of the brightness of the recorded image (in arbitrary units of the RGB system from 0 to 255) on the intensity of the incident radiation for some of the used interference filters 6. Then, the brightness of the photoluminescence domain and the background signal are measured in arbitrary units of the RGB system for each of the images in Fig. 3. The brightness of the photoluminescence signal is measured in the center of the domain illuminated by laser radiation. The brightness of the background signal is measured outside the photoluminescence domain. The obtained values of the image brightnesses are transferred using the gradation curves (Fig. 6) into the intensity of the photoluminescence signals. The difference between the background signal and the signal from the domain illuminated by laser radiation allows to determine the intensity of the photoluminescence signal. According to the obtained results, the spectral dependence of the photoluminescence intensity of the engine oil film on the water surface (Fig. 7, dashed line), obtained from a distance of 15 m, is constructed. Fig. 7 also shows the photoluminescence spectrum of the engine oil, obtained under stationary conditions using the monochromator (solid line). The difference between the spectral characteristics is stipulated by several factors: the discrete set of interference filters and the lower accuracy of the digital camera matrix compared to the photomultiplier of the monochromator. However, the characteristic curve of the photoluminescence of the engine oil, obtained from a distance of 15 m, is quite comparable with that under stationary conditions, which allows the identification of thin films of engine oil on the water surface from large distances.

1. Chirita A., Kukhtarev N., Kukhtareva T., Gallegos S. Remote sensing and characterization of oil on water using coherent fringe projection and holographic in-line interferometry. Optical Engineering, 2013, 52(3), p. 035601-035605

Claims (1)

Method for identifying thin films of petroleum products according to their photoluminescence spectrum at a distance, which includes illuminating the studied object, which is located on the water surface, with optical radiation causing photoluminescence from a remote distance with the simultaneous recording of a series of images of the photoluminescence range of the object using a digital camera through a system of narrow-band interference filters, while during digital image processing the photoluminescence signal, caused by illumination with optical radiation, is separated from the light background fully reflected from the object, and the petroleum product film is identified by comparing the obtained photoluminescence spectrum of the studied object with the standard photoluminescence spectrum of petroleum products.