SE520897C2 - Identifying types of wood during timber sorting, by comparing spectrometric analysis data with reference data for known logs - Google Patents

Abstract

A bark-free part of the log is analysed using a spectrometric technique and the resulting data is compared with reference data for known logs. A method for identifying the type of wood in a log or trunk during timber sorting comprises analysing a bark-free part of the log using a spectrometric technique that generates spectral data, and comparing this data with reference spectral data obtained from reference logs. The reference spectral data has been calibrated according to the type of wood in the reference log using a multiple variable analysis technique.

Description

25 30 35 520 897 2 Thus, it can be determined whether an analyzed log originates from the top, bottom or part of the middle section of the tree trunk from which the log has been sawn off.

The present invention is particularly useful in sorting different timber ranges.

In one embodiment, the log is analyzed while it is in motion, for example while it is being transported on a conveyor.

Preferably, the spectrometric method means that the log is irradiated by irradiation in the wavelength range from preferably about 400 to about 2500 nm, and especially from about 600 to about 2300 nm.

In a preferred embodiment of the invention, the diffuse reactance from and / or the absorbance of said radiation of the irradiated log is measured.

The multivariate analysis can be performed using a partial least squares projection on latent structures (PLS), main component regression (PCR), main component analysis (PCA), canonical correlation, multilinear regression analysis (MLR), back regression with svar your answers, a factor analysis, discriminant analysis. Systems with neural networks (NN) and / or systems with artificial intelligence (A1) can be used to perform the analysis. In a preferred embodiment, the fl variable analysis is performed using PLC. In another preferred embodiment, the variable analysis is performed using NN and / or AI.

In accordance with the invention, it has been shown that it is possible to directly determine the type of wood in a log by detecting spectra of the log, and by converting these spectra to said type of wood by a calibration technique with fl your variables. The spectrometric method used may be an absorption spectrometry, reactance spectrometry, transmission or transmission spectrometry, and it is preferably applied in the visible / near infrared (VIS-NIR) wavelength range, especially in the near infrared (NIR) wavelength range.

Spectra can be subject to further data processing by using values from olika your different discrete wavelengths from each particular spectrum. Here it should be understood that the radiation used in the spectrometric procedure directly affects the log.

The present method can be performed by means of a device placed at a distance from the process and containing a light source, a detector, electronic components and other components necessary to transmit a signal through an opto fi to the test piece, where the light is transmitted through or reflected on or partially through the specimen. The resulting signals are fed back to the detector by an accompanying optical cable and recorded.

In the spectrometer, the light is converted into an electrical signal which is transmitted to a computer where the spectrum from a previously stored reference scan can be referred to, eg subtracted from, the sample bit spectrum and a corrected reference spectrum is calculated.

The detector may have measuring ranges corresponding to, for example, 10 nm, preferably 2 nm, and more preferably 1 nm or less. The detection can be performed within the VIS-NIR-IR-520 897 3 wavelength range corresponding to between 180 nm and 2500 nm. This can be done by using a scanning instrument, a diode array instrument, a Fourier conversion instrument or any other similar equipment known to those skilled in the art.

In certain embodiments of the invention, the spectrometric method may be performed by means of an image generating device, such as an image generating NIR device or a color video camera, in combination with image analysis.

An estimate of the wavelengths with respect to absorption or transmission can provide characteristics that are essential to the analysis. By applying fl variable variable procedures to the obtained spectra, it is then possible to ignore wavelengths that do not contain information that contributes to the analysis, even if the measurement will contain information from the entire wavelength range.

According to one embodiment, the present method comprises the following steps: (I) developing a calibration model through (I.a) reference spectral data for reference logs; recording, by a spectrometric method, raw (I.b) processing of the raw reference spectral data to reduce noise and adjust for operation and diffuse light scattering; (I.c) calibrating the processed reference spectral data with the known woods of the reference logs by performing a data analysis comprising fl variable analysis; and (II) recording, by said spectrometric method, raw spectral data for a log of an unknown wood species; processing the resulting raw spectral data to reduce noise and adjust for operation and diffuse light scattering; and applying the developed calibration model to the processed spectral data to determine the unknown wood species.

The multivariate analysis during step (I.c) preferably involves the transfer of processed reference spectral data to latent variables; and during sub-step (II), processed reference spectral data are preferably transferred to latent variables in the same way as in (I.c), and the developed calibration model is applied to the latent variables to determine the unknown wood species. The conversion to latent variables can be performed using PCA. This embodiment is discussed in more detail below.

(I) DEVELOPMENT OF A CALIBRATION MODEL The types of wood are determined in the traditional way for a number of reference logs. This information is then used in the development of a calibration model where the three sub-steps discussed below are applied to the recorded absorption, reactance or spectrum emission from said logs.

(I.a) Development of calibration sets The model calibration sets consist of a large number of absorption or transmission spectra from reference logs of known woods, which should preferably be representative of the production line.

The calibration sets are used in the variable algorithms to establish the resulting model.

(I.b) Data processing To reduce the noise and adjust for the baseline operation, the spectral raw data can be processed. The processing can also reveal hidden information such as the identity of obviously different spectra, or the lack of identity between obviously very similar spectra. Therefore, the assumptions leading to Beers' law (which means that for a given absorption coefficient and the length of the optical path in absorption media, the total amount of light absorbed is proportional to the molecular concentration of the specimen) are not always met in the complex system of the specimens. This is due to a number of factors, which are often present in industrial and laboratory specimens. Another complicating factor is the variations in light scattering, which is due to particles in the specimen. Various theories have been developed to solve this problem and the most commonly used are: the Kubelka-Munk transformation, which takes into account absorption and proliferation; and the multiplicative scatter correction, where each spectrum is corrected for both displacement and inclination by comparing it with an "ideal spectrum" (the average spectrum). Another way of linearizing spectral data also takes place with the help of derivatives, for example up to fourth-order derivatives (A Savtizky, M J E Golay, Anal. Chem. 36, 1627-1639) (1964), which is included here as a reference). The derivatives of the spectrum result in a transformed spectrum, which is solely due to the relative changes between the adjacent wavelengths and it has been shown that the peak intensities of the derived spectra tend to be more linear with the concentration (TC O'Haver, T Begley, Anal. Chem. 53). , 1876 (1981)). The linearization can also be performed using Fourier transform, or using the normal standardized variable transformation described in R J Barnes, M S Dhanoa and S J Lister, Appl. Spectrosc., Vol. 43, No. 5, pages 772-777 (1989). Another useful method, orthogonal scatter correction (OSC) is described by Svante Wold et al. In Chemometrics and Intelligent Laboratory Systems 44 (1998), pages 175-185.

(I.c) Data analysis Data analysis using fl variable techniques then enables the development of the calibration model. Several different variable techniques can be used, such as PCA, PLC, PCR, MLR and discriminant analysis. Neural network systems and / or systems with artificial intelligence can also be used to perform the analysis, especially if the spectrometric procedure involves or is combined with image analysis.

(II) DETERMINATION BY APPLYING THE CALIBRATION MODEL As soon as a calibration model has been developed, the unknown type of wood can be determined by recording the absorption or transmission spectrum, in accordance with (I.a). Processing of the spectral raw data thus obtained according to (l.b); optionally performing a data analysis regarding the processed spectral data in accordance with (I.c); and applying the developed calibration model to the data thus obtained.

To further illustrate the present invention, an example of an embodiment of the present invention will now be described below, with reference to the accompanying drawings, in which: Figure 1 illustrates the application of a PCA model to a data matrix based on spectrometric reactance measurements on specimens from pine and spruce logs.

Example Reference spectra from 53 sawn specimens of pine and spruce stalks were recorded using a professional probe and a NIR spectrophotometer system 6500. The probe was placed against the surface of the bark and the reflected radiation was measured. The measuring range of the probe corresponded to 400-2500 nm, ie the visible and the near infrared range. Every other wavelength was scanned and all 53 spectra were combined into a data matrix in the order 53 x 1050 (objects x variables). The wavelength ranges 400-900 nm and 2300-2500 nm were then removed and not used in the variable analysis. A PCA model was applied to the data matrix to find out if the measurements could be divided into different groups. The result of this PCA assimilation is illustrated in Figure 1 in which t [1], t [2], t [3] represent the first three main components, the black spheres representing pine with smooth bark, the gray spheres representing spruce and the white the balls represent pine with rough husk. The first three components of the model show a clear grouping into three classes. The spruce values are collected in the middle of the diagram, while the pine values are collected on each side of the spruce class. Here it is assumed that the reason why the pine values are collected in two classes may be that there is a significant difference between rough and even bark. Subsequently, a PLC discriminant analysis was performed to find out whether it would be possible to predict whether the various objects in the data matrix originated in pine or spruce. About one-third, 17 objects, were used in a test set, while the remaining 36 objects were used to build a model for predicting the objects in the test set. In the model, all pine objects were named "1" and all spruce objects were named "2". Table 1 below shows how the objects in the test set were predicted, ie if they were predicted as "1" or "2". All objects in the test set were classified correctly based on the model. An object with a value of <1.5 was classified as pine while an object with a value> 1.5 was classified as spruce. RMSEP (RMSEP = error prediction of the rms value) corresponded to 0, 271258. 520 897 6 Table 1 Observation number Variable 1 (observed) Variable 1 (predicted) 3 1 1.3632 6 1 1.3152 9 1 1.3589 12 2 2.0718 15 1 1.4072 18 2 1.7646 21 1 1, 3292 24 1 1,1678 27 2 1,9251 30 1 1,4549 33 2 1,8457 36 1 1,2188 39 2 1,7552 42 1 0,86507 45 2 1,7899 48 1 0,84328 51 2 1, 6889

Claims (9)

10 15 20 25 30 35 520 897 7 Patent claims 1. A method for determining the type of wood in a log or tree trunk when sorting timber, characterized in that the method comprises: - analysis of an unbarked part of the log by a spectrometric method which gives spectral data, and - comparison of said spectral data and reference spectral data obtained by said spectrometric method from reference logs, which reference spectral data have been calibrated according to the woods of said reference logs, by an fl variable analysis. Method according to claim 1, characterized in that the method comprises: - comparison between said spectral data and reference spectral data obtained by said spectrometric method from at least partially unbarked reference logs, wherein reference spectral data has been calibrated according to the wood species of at least partially unbarked logs, by a . 3. A method according to claim 1, characterized in that the log is analyzed while it is in motion. A method according to claim 1, characterized in that said spectrometric method means that - the log is irradiated by an irradiation within the wavelength range from about 400 to about 2500 nm, and - the diffuse reflectance from and / or the absorbance of said radiation of the irradiated the log is measured. 5. A method according to claim 4, characterized in that said wavelength range corresponds to from about 600 to about 2300 nm. A method according to claim 4, characterized in that said wavelength range corresponds to from about 900 to about 2300 nm. A method according to claim 1, characterized in that said al variable analysis is performed by means of partial minimum regression, main component regression, main component analysis, canonical correlation, back regression with svar your answers, or a combination of these. A method according to claim 1, characterized in that said method comprises the following steps: (I) developing a calibration model through (La) reference spectral data for reference logs; recording, by a spectrometric method, the raw (Ib) processing of the raw reference spectral data to reduce noise and adjust for operation and diffuse light scattering; (I.c) calibrating the processed reference spectral data with the known woods of the reference logs by performing a data analysis comprising fl variable analysis; and 520 897 8 (II) recording, by means of said spectrometric method, raw spectral data for a log of an unknown wood species; processing the resulting raw spectral data to reduce noise and adjust for operation and diffuse light scattering; and applying the developed calibration model to the processed spectral data to determine the unknown wood species. Method according to one of Claims 1 to 3, characterized in that the spectrometric method comprises irradiating the log and measuring the reflected radiation.