DE2546253A1 - Spectral analyzer and colorimeter photo: receiver - has several light sensitive receivers with differing spectral sensitivities covered with block filter(s) - Google Patents

Abstract

Spectral analyser and colorimeter photo-receiver has several light sensitive receivers with differing spectral sensitivities. The light sensitive sides of the receivers are covered iwth a filter and one or more corresponding, location independent, block filters. The spectral transmission rate of the filter is a continuous location dependent quantity. One surface (2) of the photoelectronic receiver (1) has a wind out. The light sensitive sides of the photoelements, photodiodes (3) or phototransistors are vapour deposited or bonded on the bottom of the wind out which may contain a double row of ten diodes.

Description

Photo receiver for a spectral analysis and fat measuring device with several

light-sensitive receivers in the invention is a photoreceiver for a spectral analysis and color measuring device with several light-sensitive Recipients.

In many areas of industry, such as the chemical, paper, Printing, plastics, paint and food industries as well as in state examination offices, are measurements to determine the spectral distribution of the visible and invisible electromagnetic radiation is necessary. These measurements are also the basis for Method of color measurement. With spectral analyzers, e.g. with Mbnochromators, these measurements are carried out. Two methods for the spectral decomposition of light are mainly used: 1. the process of refraction through Prisms 2. the interference method (diffraction).

In the case of the interference method, a distinction is made between further methods, which Use grids or very thin layers to calculate the radiation to be measured.

Devices that use the former include the so-called prism monochromators or prism double monochromators. With these Devices, the light falling through an entrance slit is directed onto a prism and broken down by this into its spectral components. A narrow part of the disassembled Spectrum is available at the exit slit. With the double monochromator two prisms connected in series. This achieves a higher spectral Purity of the filtered spectral range. By rotating the prism (s) the transmitted spectral range can be continuously changed.

The so-called grating monochromators work according to the interference method. Instead of a prism, a line grating is used to break down the radiation used. Here, too, the entry and exit slits are used. By turning of the grating, the transmitted spectral range can also be continuously changed.

The interference behavior of thin layers is determined by the interference filter monochromator exploited. Interference filters are used one after the other in the beam path Narrow pass band switched on, with the radiation to be split being the The region with the wavelength of the center of gravity is the least attenuated will. A constant change of the pass band is not possible.

All devices listed above measure for the purpose of spectral analysis both in terms of the wavelength of the passband and the inherent transmittance (Light intensity) can be calibrated or calibrated. The wavelength calibration takes place here by means of spectral lamps, whereas the intrinsic transmittance tt (X) by means of a radiation source with known spectral radiance distribution LeX (e.g. the black body with its calculable Planck radiation function) is determined. This twofold Calibration of a spectrum analyzer requires a lot of effort and is often just to drive through in state institutes.

In addition, these devices if a certain accuracy of the Measurement to be achieved is very expensive. For example, measurements in the interference monochromator at least 30 filters of the highest precision are used, the pass band of which is a maximum of 10 Can be nanometers in size in order to determine a color to be measured as precisely as possible. Furthermore, the measurements with such devices are very time-consuming, since one after the other individual lines of a given spectrum have to be measured. Also disadvantageous The thing about these devices is that they have to be manufactured very precisely and because they are made from many individual components exist and must be operated with great care.

The object of the invention is to avoid all these disadvantages and to create a robust measuring device which can be calibrated with simple means and which despite the low demands on the precision of the components used has a very high spectral resolution.

According to the invention, these tasks are achieved by a photo receiver for Spectral analysis and color measuring devices with several light-sensitive receivers thereby solved that at least some of the receivers have different spectral sensitivities own. An embodiment of the invention is characterized in that no Receiver has a spectral sensitivity that corresponds to that of another Another embodiment can be seen in the fact that the photosensitive sides the receiver are covered with a filter whose spectral transmittance is a constant, position-dependent quantity.

A still further development of the invention is such that the light-sensitive sides of the receiver are covered with several filters, whose spectral transmittance are continuously variable depending on the location.

Another advantageous embodiment is that of the filters with location-dependent variable transmittance filter with predominantly high and / or Low-pass behavior (block filter) are connected upstream. Another inexpensive design is such that the filters with constant, location-dependent transmittance have an interference curve line filters are. Another favorable design is such that the recipient are arranged in a matrix in a plane.

Another favorable design is that of the recipients output signals. automatically via a multiplexer to an analog-to-digital converter and sent from this to a computer.

Another favorable design is that in the computing device Calibration values the spectral sensitivity of the individual receivers are stored, or the computer can access these calibration values.

Another favorable design is that there is a computer program in the computer which calculates the spectral irradiance to be measured.

Another favorable design is such that the calculated spectral Illuminance levels are output on output devices in digital or analog form will.

Another favorable design is such that the measurement results can be displayed on a display device.

Another favorable design is such that a calculation of a Color value of a measured light with the help of or stored in the computer Standard spectral value curves x (, y (X) and z (ß) accessible to him are carried out and output will.

Another favorable design is such that several color measurements and their mutual color difference is calculated automatically.

The effect of the invention, which is surprising to the person skilled in the art, is therein to see that to achieve a high spectral resolution not components very high precision nits are used, but precisely those that are known to the expert must appear to be flawed, as it were. The more different, i.e.

the more imprecise in the traditional sense for the expert, the better is the resolving power of the photoreceiver according to the invention. The unforeseeable one The effect is due to the fact that in the calibration necessary for all these devices, Parameters of the individual recipients are determined, each of which, taken individually, are flawed, but together influence each other in a positive way, that their discrepancies compensate each other.

In picture 1 is one of the possible designs of a photoreceiver shown according to the invention. With 1 there is a photoelectronic receiver (PE), in an embodiment known under the term "chip construction". The cuboid PE points on one of its surfaces 2 one window-like opening, on the bottom of which the photosensitive sides of photo elements Photodiodes 3 or phototransistors are vapor-deposited or bonded. With this one For example, the window contains a double row of ten diodes each, as shown by the grid indicated. Phto receiver with up to 64 photodiodes in a similar Arrangements, so-called photo arrays, are also used. Because of a better one Their representation was dispensed with for clarity.

The signals emitted by the photodiodes can be transmitted to electrical Feeders 4 are removed. The photo receiver is on side 3 with a Interference line filter 5 and corresponding "block filters" 5 a covered. Light 6 of a spectral composition incident from above passes through it Interference line filter 5, the "block filter" 5a and is corresponding to the locally different spectral transmittance weakened, so that on the Photodiodes fall light types of different spectral compositions.

With the picture 2 an arrangement is shown which is suitable for a To calibrate photoreceiver according to the invention. From a monochromator 7 is Light 8 of a narrow wavelength range is directed onto a tilting mirror 9. from there is the light 8 when the tilting mirror is shown in dashed lines Position 9 a is deflected in the direction of a photo element that with regard to its spectral sensitivity is known. By turning the tilting mirror 9 in the position 9b then becomes the unknown with regard to its spectral sensitivity Irradiated photoreceiver in one embodiment according to the invention. From the comparison The sensitivity of the photocurrents emitted by both receivers is obtained SkCr; ) of the individual photo elements, where X is the wavelength of the monochromatic Light of an i-th wavelength and n is the number of the individual element of the photoreceiver is. If one measures all n individual elements at k different wavelengths, one obtains a quadratic sensitivity matrix.

If now a photoreceiver, whose sensitivity matrix (calibration matrix) was determined in the manner just described, with light of unknown spectral Irradiated distribution, so can the values of the emitted by the photoreceiver Signals using this calibration matrix can easily be converted into the actual values of the unknown Lichs are converted. The result is a Stair curve the spectral distribution of the light. However, the more individual receivers are used, the finer the structure of this step curve becomes.

Figure 3 is a block diagram of a colorimeter according to the invention laid down. Falls on the light-sensitive side 12 of a photoreceiver 13 Light of unknown spectral distribution. The signals of the individual photo elements are fed to a multiplexer, which uses an analog-to-digital converter 15 sent to a computer 16. The calibration matrix described above is in the computer 16 of the photoreceiver 13 is stored. A calculation program determines from the received Signals and the calibration matrix the spectral distribution of the irradiance. In the end the results of this calculation are output by the computer 16 on a display device 17. The use of printers and / or XY writers is also beneficial as output devices. It is also very preferable to add a part of the calculation program to the calculation to expand the color value of a light to be measured.

To do this, it is necessary to save the so-called standard spectral value curves x (), y () and z () in the computer. As described in the specialist literature, the color value of a light is calculated using color value components according to the formulas: Here, X, Y and Z are the standard color values, w a constant, Ee the irradiance at a wavelength x, y and z (X) the standard spectral values and X the wavelength. So-called standard color value proportions then result from the formulas: It is favorable for the user of such color measuring devices if standard color values and standard color value components are communicated to him at the same time on the display device 17. It is also advantageous to take multiple color measurements from multiple blank pages

Claims (15)

Light sources to save uiid their mutual loaf spacing with to calculate and enter the program in the computer. P A T E N T A N 5 P R (J C H E (% 1st photo receiver for spectral analysis and color measuring device with several light-sensitive receivers, characterized in that, that at least some of the receivers have different spectral sensitivity from one another own. 2. Photo receiver according to claim 1, characterized in that no Receiver has a spectral sensitivity that corresponds to that of another. 3. Photo receiver according to claim 1 or 2, characterized in that that the light-sensitive sides of the receiver with a filter whose spectral The transmittance is a constant, location-dependent variable and one or more corresponding ones location-independent "block filters" are covered. 4. Photo receiver according to claim 1, 1 or 3, characterized in that that the light-sensitive sides of the receiver are covered with several filters, whose spectral transmittance is continuously variable depending on the location. 5. Photo receiver according to claim 3 or 4, characterized in that that the continuously location-dependent filters are Interferenzlinienverl on the filter. 6. Photo receiver according to one of claims 1 to 5, characterized in that that the receivers are arranged in a matrix-like manner in one plane. 7. Photo receiver according to one of claims 1 to 6, characterized in that that the signals emitted by the receivers are automatically transmitted a Multiplexer fed to an analog-to-digital converter and from this a computer be sent. 8. photoreceiver according to claim 7, characterized in that in the computing device calibration values of the spectral sensitivity of the individual receivers are stored, or the computer can access these calibration values. 9. photoreceiver according to claim 8, characterized in 'that im Computer runs a computer program which determines the spectral irradiance to be measured calculated. 10. photoreceiver according to claim 9, characterized in that the calculated spectral irradiance on output devices in digital or output in analog form. 11. photoreceiver according to claim 10, characterized in that the results can be printed out. 12. Photo receiver according to claim 11, characterized in that the Measurement results are displayed on a display device. 13. Photo receiver according to claim 9, 10, 11 or 12, characterized in that that a calculation of a color value of a measured light with the help of im Standard spectral value curves x (#), y (#) stored by the computer or accessible to it and z (#) can be performed and output. 14. Photo receiver according to claim 13, characterized in that several Color measurements are saved and their mutual color difference is calculated automatically will. 15. Photo receiver according to claim 4, characterized in that the Filters with location-dependent variable transmittance Filters with predominantly Eloch and / or low-pass filters ("block filters") are connected upstream.