BR102018067972B1 - METHOD AND SYSTEM FOR MEASUREMENT OF TRANSMITTANCE CHARACTERISTICS OF TRANSLUCENT OBJECTS - Google Patents

Abstract

METHOD AND SYSTEM FOR MEASUREMENT OF TRANSMITTANCE CHARACTERISTICS OF TRANSLUCENT OBJECTS The present invention falls within the area of electrical engineering, more particularly related to methods and equipment for analyzing transmittance in translucent materials. Thus, the present invention provides a method for measuring transmittance characteristics of translucent objects, the method comprising the steps of: a) determining weighting functions with which the measurements will be made; b) determine coefficients of linear combinations between transmittance values with previously known weighting functions; c) determine a measurement reference value; d) emit a spectrum of radiation; d) measure transmittance values of the translucent object by detecting the response of the radiation spectrum that passes through the translucent object; e) calculate transmittance values of the translucent object for the characteristic to be measured (37) based on the values measured in step e) and the reference value determined in step c).

Description

FIELD OF INVENTION

[001] The present invention falls within the area of electrical engineering, more particularly related to methods and equipment for transmittance analysis in translucent materials.

FUNDAMENTALS OF THE INVENTION AND STATE OF THE ART

[002] To measure the transmittance of a translucent object, it is necessary to measure the transmittance of a sample for each wavelength with a spectrophotometer and, based on these measured values and a weighting function of interest, calculate the weighted average .

[003] The need for a spectrophotometer and a trained professional to operate it means that this form of measurement is restricted to industrial and scientific environments. The spectrophotometer is the best instrument for measuring transmittance, as no other device or method is as accurate.

[004] An alternative way to measure transmittance consists of using a light source and a photosensor. In this way, transmittance is measured with a spectral weighting function numerically equal to the term-to-term product of the spectral emission of the light source and the spectral response of the sensor.

[005] Such measurements with this method are much faster (done in seconds), require simpler components than those with spectrophotometers and can be programmed so that even laypeople can carry them out. However, the measurement weighting function is limited to the choice of hardware.

[006] In this sense, when measuring light transmittance in translucent materials, the most important parameter for such analysis is the spectral weighting function used in the measurement.

[007] Such a spectral weighting function is chosen taking into account the objective of the measurement, for example, if the interest is to evaluate how much of the backlight of a liquid crystal display is perceived by the user's eye, it is Measure the transmittance of the screen with a spectral weighting function numerically equal to the term-to-term product of the backlight spectral emission with the spectral response of the human eye.

[008] In transmittance measurements with a light source and photosensor, the baseline must first be measured, the response of the sensor to the light source without the sample between them. Secondly, the sample to be measured is positioned between the light source and the sensor and the light that reaches the sensor attenuated by the sample is measured. For sensors with linear response, the transmittance value with the weighting defined by the hardware is equal to the ratio of the measurement with the sample to the baseline. For sensors with non-linear response, the appropriate correction of the measured values is made and then the ratio is analogous.

[009] Thus, prior art documents describe technologies that present a single spectral weighting function determined by the specific characteristics of what is desired to be measured and its relationship with the final result.

[010] Examples of this type of technology are the Chinese documents CN 202267594 U and CN 103868674 A, in addition to the German document DE 102013003558 A1, the European document EP 0819923 A2 and the North American documents US 5859709 A and US 6559945 B1, for example .

[011] Chinese document CN 202267594 U describes a simplified 3D glasses testing equipment, which comprises emitters for transmitting light through the glasses and signal reception and processing elements for determining the quality of the glasses to be tested, eliminating the manual tests usually used.

[012] Chinese document CN 103868674 A describes color filter testing equipment, which comprises the transmission of light of different spectrums through a color filter and signal reception and processing elements to determine color transfer. by the filter to be tested.

[013] Similarly, German document DE 102013003558 A1 describes a simplified spectacle color testing equipment, which comprises light emitters for transmitting light through the spectacles and signal reception and processing elements for determining the quality of the spectacles. colors transmitted by the lens of the glasses to be tested.

[014] Furthermore, North American documents US 5859709 A and US 6559945 B1 describe the determination of optical characteristics of devices with complex systems, which use specific components (integration spheres and devices that separate light into monochromatic components, for example), which measure reflection characteristics of samples, how much of each wavelength is reflected by the sample, and has a light acquisition system similar to a spectrophotometer.

[015] Finally, European document EP 0819923 A2 describes a system that performs measurements of optical characteristics with more than one weighting function to achieve the final result, which, however, is a system that measures the transmittance for each length of wave, requires filters to discretize the emission of the light source at each length that is desired to be measured and requires a number of linearly spectrally independent light beams, equal to the number of wavelengths that are desired to be measured.

[016] However, when the documents mentioned above are capable of modifying the weighting function when desired, using the same hardware, the systems are composed of complex components, and do not perform different measurements determined by different objectives, they only perform measurements for each wavelength and then calculate the weighted average. Furthermore, such documents that use extremely complex components require specialized technicians for analysis. Documents that use simplified components maintain a constant weighting function and are not able to modify it.

[017] Furthermore, the dangers of using sunglasses unsuitable for traffic (drivers, pedestrians, cyclists, for example) are unknown to the general public, as is the existence of minimum requirements that sunglasses must meet to be considered safe for traffic. Excessively dark lenses can prevent recognition of traffic lights and objects at a safe distance. Lenses that excessively attenuate one or more colors of traffic lights in relation to the attenuation of visible light may cause the user to confuse signals. Both cases are very dangerous and can be avoided if the user is aware of them and has access to information about their own sunglasses.

[018] In this sense, the systems for traffic light identification testing of sunglasses that exist today are not portable and only use spectrophotometers or equivalent, scientific equipment that, as previously described, must be operated by qualified people and not by laypeople, and there is no products operated by laypeople that measure light transmittance in sunglasses, with the purpose of identifying transmittances of traffic lights.

[019] Thus, a difference of the present invention is to allow the measurement of transmittance of translucent objects with an approximation of the weighting of interest, variable depending on the analysis, using light sources and photosensors, without having the same hardware limitation as several of the proposed methods. in previous techniques, that is, allowing the measurement of transmittance in translucent materials with the possibility of adjusting the spectral weighting function without changing its components or needing successive measurements to train artificial intelligence, as currently used.

[020] Furthermore, another difference of the present invention is that the proposed method and system allow the measured value to be compared with ranges of values of interest and the sample to be automatically classified in the range to which it belongs, such as classifying sunglasses in different categories, depending on the degree of darkening of your lenses.

[021] Thus, although the method and system presented have an unrestricted purpose for transmittance measurements in the range from ultraviolet to infrared, they are especially appropriate for the sunglasses sector, calculating ultraviolet protection, blue light protection, category of lenses, infrared protection, among others. Furthermore, it is possible to check whether sunglasses are suitable for traffic (drivers, pedestrians, cyclists, for example), that is, whether they meet traffic light tests proposed in current standards for general-use sunglasses.

[022] Finally, it is also expected that the method and system proposed here allow measurements with simple and portable components that can replace scientific equipment.

BRIEF DESCRIPTION OF THE PRESENT INVENTION

[023] The present invention relates to a method of measuring the transmittance characteristics of translucent objects, the method comprising the steps of: a) determining weighting functions with which the measurements will be made; b) determine coefficients of linear combinations between transmittance values with previously known weighting functions; c) determine a measurement reference value; d) emit a spectrum of radiation; e) measure transmittance values of the translucent object by detecting the response of the radiation spectrum that passes through the translucent object; f) calculate transmittance values of the translucent object for the characteristic to be measured based on the values measured in step e) and the reference value determined in step c).

[024] Preferably, the step of determining the weighting functions is carried out based on the measurement objective, in addition to the weighting functions being determined based on functions determined by characteristics of the hardware components, ideally based on characteristics of at least one light source used for the step of emitting a radiation spectrum and at least one sensor used for the step of measuring transmittance values. In this sense, the step of determining the coefficients of linear combinations is carried out to obtain approximate values of measurements of the transmittance characteristic with the previously determined weighting functions.

[025] Such a method may alternatively further comprise a step of comparing the calculated transmittance characteristic with pre-defined requirements, as well as signaling whether the pre-defined requirements have been met, wherein one of these pre-defined requirements is whether a lens of sunglasses is suitable for traffic, according to the criteria of a specific standard in force.

[026] Preferably, the step of measuring transmittance values of the translucent object detects responses in which the radiation spectrum passes through the translucent object, and can additionally measure reference values by detecting responses in which the radiation spectrum does not pass through the translucent object and comparing such measured values. Furthermore, the emitted radiation spectrum is, preferably, a visible light spectrum in the range between 380 nm and 780 nm and, optionally, steps c), d) and e) can be carried out concomitantly.

[027] A system for measuring transmittance characteristics of translucent objects is also provided, the system comprising at least: a processor; a sample of the translucent object to be measured; a light source; and a sensor; wherein the sample is positioned between the at least one light source and the at least one sensor, the system being configured so as to: a) determine weighting functions with which measurements will be made using the processor; b) determine coefficients of linear combinations between transmittance values with weighting functions previously known through the processor; c) determine a measurement reference value using the processor; d) emit a spectrum of radiation through at least one light source towards at least one sensor; e) measure values of the radiation spectrum that passed through the sample, through sensors, by detecting the response of the radiation spectrum that passed through the sample; and f) calculate, through the processor, transmittance values of the translucent object for the characteristic to be measured based on the values of the radiation spectrum that passed through the sample, measured by at least one sensor and the measurement reference value determined by the processor .

[028] Preferably, the determination of the weighting functions by the processor is carried out based on the measurement objective, and the determination of the weighting functions by the processor is based on weighting functions determined by hardware components, ideally based on weighting functions. weighting determined by characteristics of the at least one light source and the at least one sensor.

[029] Furthermore, the system preferably determines the coefficients of linear combinations by the processor to obtain approximate values of measurements of the transmittance characteristic with the previously determined weighting functions and subsequently adjust the weighting functions determined by adjusting the coefficients. of linear combinations previously determined according to system characteristics.

[030] Alternatively, the system may additionally compare the transmittance characteristic with pre-defined requirements, and further signal whether the pre-defined requirements have been met, wherein the pre-defined requirements particularly may be whether the sunglasses lenses are suitable for traffic.

[031] Preferably, the system must comprise an encapsulation that prevents the entry of light other than at least one light source in the region destined for the sample to be measured and at least one sensor.

[032] Still, alternatively, in such a system the at least one sensor may comprise at least two sensors, being a measurement sensor and a reference sensor. In this sense, the measurement of reference values is preferably carried out by detecting responses in which the radiation spectrum does not pass through the sample and comparing both, whereby determining a reference value when measuring reference values can be carried out by means of the sensor reference and, the measurement of the transmittance values of the sample can be carried out using the measurement sensor simultaneously.

[033] Such emitted radiation spectrum is, preferably, a visible light spectrum in the range between 380 nm and 780 nm.

BRIEF DESCRIPTION OF FIGURES

[034] The present invention will now be described below with reference to typical embodiments thereof and also with reference to the attached drawings, in which:

[035] Figure 1 is a representation of a block diagram representing the elements of a device according to a preferred configuration of the present invention;

[036] Figure 2 is a representation of a block diagram representing the elements of a device according to a second configuration of the present invention; It is

[037] Figure 3 is a representation of a flowchart representing the control method according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[038] As previously described, the present invention falls within the area of electrical engineering, more particularly related to methods and equipment for transmittance analysis in translucent materials.

[039] As can be seen in figure 1, the system according to the present invention comprises light sources 1, a device or sample 2 to be measured, sensors 3, in which weighting factors 4 are applied to specific measurements, which present results 5 by means of a control 6, preferably an electronic control system.

[040] As represented in figure 1, light sources 1 and sensors 3 must cover the spectral region used in the spectral weighting functions of interest, which are preferably within the visible spectrum region, between 380 nm and 780 nm. In this case, sample 2 must be positioned between the light sources and the photosensors to be measured.

[041] A baseline is measured without the sample attenuating the light reaching the sensor, and such a measurement can be made before the sample is positioned or even after it is removed, or alternatively with the use of reference sensors, i.e. , extra sensors for simultaneous measurement of sample and baseline transmittance.

[042] Figure 2, in turn, illustrates the case in which reference sensors are used, that is, the system comprises measurement sensors 3a and reference sensors 3b. A foreseen control 6 is a controller capable of turning on and off the light sources 1, obtaining measurements from the sensors 3, storing and adjusting the coefficients of linear combinations, carrying out the calculations necessary for the measurement and storing and/or displaying the results 5 for an end user.

[043] To ensure that ambient lighting does not interfere with measurements, it is necessary that the structure of the system prevents the entry of external light, so that only known light sources pass through the samples and reach the sensors.

[044] As can be seen in figure 3, a flowchart of the measurement method according to the present invention is presented. In this sense, the system is initially in standby mode 31 until the user signals that he wants to measure 32 a sample. After such signaling, a calibration 33 is performed, measuring baselines for each combination of light source and sensor that will be used in the final measurement. The user positions sample 2 to be measured correctly between light sources 1 and sensors 3.

[045] After this step, measurements 35 are carried out. Alternatively, the calibration, instead of being carried out prior to positioning 34 of sample 2, can be measured in measurement step 35 by reference sensors 3b. This practice of measuring the baseline close to the sample eliminates errors due to temporal variations in emission from light sources.

[046] From the baselines and sample measurements, the transmittances of the sample are calculated with the known weights determined by the components 36. Using the transmittances with known weights and the coefficients of the linear combinations, the transmittances 37 of the sample are calculated with the considerations of interest.

[047] In a specific embodiment, pre-defined requirements 38 are tested to determine characteristics of samples 2, for example, if a minimum of light passes through the lens of sunglasses, they may be suitable for certain situations. Obviously, step 38 is optional, and there may be interest only in transmittance measurements without specific tests.

[048] Finally, the results are displayed and/or stored. Such a stage of displaying 39 the results may only comprise whether the requirements were met, only the measured values with weights of interest or the measured values compared with requirements. Finally, the user can then signal the desire to return to standby mode 40 or start a new measurement.

[049] Thus, a possible change in the interest weighting functions, whether due to a change in the standard, a change in the test of interest, or for another reason, is easily accomplished with changes to the controller parameters.

[050] Although the immediate use of the device is to test sunglasses to check suitability for traffic, it can also be used to carry out other transmittance tests within the visible range of the spectrum on different translucent objects, such as transmittance tests of LCDs, or color transmittance of glasses, glasses or other systems.

[051] Thus, the present invention provides a method for measuring the transmittance characteristics of translucent objects, the method comprising the steps of: a) determining weighting functions with which the measurements will be made; b) determine coefficients of linear combinations between transmittance values with previously known weighting functions; c) determine a measurement reference value; d) emit a spectrum of radiation; d) measure transmittance values of the translucent object by detecting the response of the radiation spectrum that passes through the translucent object; e) calculate transmittance values of the translucent object for the characteristic to be measured 37 based on the values measured in step e) and the reference value determined in step c).

[052] In such a method, preferably step a) determines the weighting functions based on the measurement objective, for example characteristics of glasses lenses or LCD transparencies, and step b) determines the weighting functions based on functions weighting determined by characteristics of the hardware components, particularly by characteristics of at least one light source 1 used for step c) and at least one sensor 3 used for step d). In this sense, step b) determines the coefficients of linear combinations to obtain approximate values of measurements of the transmittance characteristic with the weighting functions determined in a).

[053] Alternatively, the method may additionally comprise an additional step: f) comparing the transmittance characteristic calculated in step e) with pre-defined requirements, and signaling whether the pre-defined requirements have been met, in which the pre-defined requirements - defined may be whether the sunglasses lenses are suitable for traffic.

[054] In such a method, step c) can be performed by measuring reference values when detecting responses in which the radiation spectrum does not pass through the translucent object. Preferably, the radiation spectrum of step c) is a spectrum of visible light in the range between 380 nm and 780 nm and, optionally, steps c), d) and e) can be carried out concomitantly.

[055] A system for measuring transmittance characteristics of translucent objects is also provided, the system comprising at least: a processor (6); a sample (2) of the translucent object to be measured; a light source (1); and a sensor (3); in which the sample (2) is positioned between the at least one light source (1) and the at least one sensor (3), the system being configured so as to: a) determine weighting functions with which measurements will be made by middle of the processor; b) determine coefficients of linear combinations between transmittance values with weighting functions previously known through the processor; c) determine a measurement reference value using the processor; d) emit a spectrum of radiation through the light sources 1 towards at least one sensor 3; e) measure values of the radiation spectrum that passed through sample 2, through sensors 3, when detecting the response of the radiation spectrum that passed through sample 2; and f) calculate, by means of the processor, transmittance values of the translucent object for the characteristic to be measured based on the values of the radiation spectrum that passed through the sample 2 measured by at least one sensor 3 and the measurement reference value determined by the processor.

[056] In such a system, the determination of weighting functions by the processor is preferably carried out based on the measurement objective, and the determination of weighting functions by the processor is based on weighting functions determined by hardware components, preferably based on in weighting functions determined by characteristics of at least one light source 1 and at least one sensor 3.

[057] In a particular configuration, the determination of the coefficients of linear combinations by the processor is carried out to obtain approximate values of measurements of the transmittance characteristic with the previously determined weighting functions and subsequently, adjust the weighting functions determined through adjustments of the coefficients of linear combinations previously determined, according to system characteristics.

[058] Alternatively, the system may further comprise comparing the transmittance characteristic with pre-defined requirements, and further signaling whether the pre-defined requirements have been met, wherein the pre-defined requirements may be whether the sunglasses lenses are suitable for traffic.

[059] Preferably, the system comprises an encapsulation that prevents the entry of light other than the at least one light source 1 in the region intended for the sample 2 to be measured and at least one sensor 3, wherein the at least one sensor 3 may comprise at least two sensors, a measurement sensor 3a and a reference sensor 3b.

[060] The system preferably determines a reference value by measuring reference values through reference sensor 3b and measuring transmittance values of sample 2 through measurement sensor 3a, with the emission of the spectrum of radiation and the determination of the measurement reference value and the measurement of the transmittance values of sample 2 can be carried out concomitantly. Preferably, the emitted radiation spectrum is a visible light spectrum in the range between 380 nm and 780 nm.

ADVANTAGES AND MODIFICATIONS

[061] In this way, the present invention solves the problems of previous techniques by presenting a method and system for determining transmittance characteristics of translucent objects.

[062] This method and system allows the measurement of transmittance of translucent objects with an approximation of the weighting of interest, different in each analysis, using light sources and photosensors, with no hardware limitations. Obviously, although it is described that there are no hardware limitations, the weighting functions that can be adjusted are necessarily contained both in the union of the spectral regions of the light source emissions and in the union of the spectral regions of the photosensor responses.

[063] In this way, the method and system described allow the measurement of transmittance in translucent materials with the possibility of adjusting the spectral weighting function without changing its components or needing successive measurements to train artificial intelligence.

[064] Furthermore, another difference of the present invention is to measure light transmittance, in which the proposed method and system allow the measured value to be compared with ranges of values of interest and automatically classify the sample in the range to which it belongs, such as the category of sunglasses that varies depending on how dark their lenses are.

[065] Finally, it is also expected that the method and system proposed here allow measurements with simple and portable components that can replace scientific equipment.

[066] Thus, the method and system proposed in this invention can be used to measure the luminous transmittance and transmittance values of traffic light signals (red, yellow, green and blue) in sunglasses and inform whether they are suitable for transit and its recommended use, in accordance with current standards, such as, for example, those used in international standards such as ISO 12312 and, naturally, in its version translated into Portuguese and adopted by ABNT, ABNT NBR ISO 12312.

[067] Although the invention has been extensively described, it is obvious to those skilled in the art that various changes and modifications can be made without said changes falling within the scope of the invention.

Claims (25)

1. Method of measuring transmittance characteristics of translucent objects, the method characterized by comprising the steps of: a) determining weighting functions with which the measurements will be made; b) determine coefficients of linear combinations between transmittance values with previously known weighting functions; c) determine a measurement reference value; d) emit a spectrum of radiation; e) measure transmittance values of the translucent object by detecting the response of the radiation spectrum that passes through the translucent object; f) calculate transmittance values of the translucent object for the characteristic to be measured (37) based on the values measured in step e) and the reference value determined in step c). 2. Method, according to claim 1, characterized in that in step a) the weighting functions are determined based on the measurement objective. 3. Method according to claim 1 or 2, characterized in that in step b) weighting functions are determined based on weighting functions determined by characteristics of the hardware components. 4. Method, according to claim 3, characterized in that in step b) weighting functions are determined, based on weighting functions determined by characteristics of at least one light source (1) used for step d) and at the same time least one sensor (3) used for step e). 5. Method, according to any one of claims 1 to 4, characterized in that in step b) the coefficients of linear combinations are determined to obtain approximate values of transmittance measurements of the transmittance characteristic with the weighting functions determined in a) . 6. Method, according to any one of claims 1 to 5, characterized by additionally comprising a step of: g) comparing the transmittance characteristic calculated in step f) with pre-defined requirements (38). 7. Method, according to claim 6, characterized by signaling whether the pre-defined requirements have been met. 8. Method according to claim 6 or 7, characterized in that the pre-defined requirements are whether sunglasses lenses are suitable for traffic. 9. Method according to any one of claims 1 to 8, characterized in that step e) measuring transmittance values of the translucent object by detecting responses in which radiation spectrum passes through such translucent object. 10. Method, according to any one of claims 1 to 9, characterized in that in step c) reference values are measured when detecting responses in which the radiation spectrum does not pass through the translucent object. 11. Method, according to claim 10, characterized in that steps c), d) and e) are carried out concomitantly. 12. Method according to any one of claims 1 to 11, characterized in that the radiation spectrum of step c) is a visible light spectrum in the range between 380 nm and 780 nm. 13. System for measuring transmittance characteristics of translucent objects, the system comprising at least: a processor (6); a sample (2) of the translucent object to be measured; a light source (1); and a sensor (3); in which the sample (2) is positioned between the at least one light source (1) and the at least one sensor (3), the system characterized by being configured so as to: a) determine weighting functions with which the measurements will be made measurements through the processor; b) determine coefficients of linear combinations between transmittance values with weighting functions previously known through the processor; c) determine a measurement reference value using the processor; d) emit a spectrum of radiation through the at least one light source (1) towards the at least one sensor (3); e) measuring values of the radiation spectrum that passed through the sample (2), by means of at least one sensor (3), by detecting the response of the radiation spectrum that passed through the sample (2); and f) calculate, through the processor, transmittance values of the translucent object for the characteristic to be measured based on the values of the radiation spectrum that passed through the sample (2) measured by at least one sensor and the determined measurement reference value by the processor. 14. System, according to claim 13, characterized in that the determination of the weighting functions by the processor are carried out based on the measurement objective. 15. System, according to claim 13 or 14, characterized in that the determination of weighting functions by the processor are based on weighting functions determined by hardware components. 16. System, according to claim 15, characterized in that the determination of the weighting functions by the processor is carried out based on weighting functions determined by characteristics of the at least one light source (1) and the at least one sensor (3) . 17. System, according to any one of claims 13 to 16, characterized in that the determination of the coefficients of linear combinations by the processor is carried out to obtain approximate values of measurements of the transmittance characteristic with the previously determined weighting functions and subsequently adjust the weighting functions determined through adjustments of the coefficients of linear combinations previously determined according to system characteristics. 18. System, according to any one of claims 13 to 17, characterized by additionally comprising comparing the transmittance characteristic with pre-defined requirements. 19. System, according to claim 18, characterized by signaling whether the pre-defined requirements have been met. 20. System, according to claim 18 or 19, characterized in that the pre-defined requirements are whether sunglasses lenses are suitable for traffic. 21. System, according to any one of claims 13 to 20, characterized in that it comprises an encapsulation that prevents the entry of light other than the at least one light source (1) in the region intended for the sample (2) to be measured and the least one sensor (3). 22. System, according to any one of claims 13 to 21, characterized in that the at least one sensor (3) comprises at least two sensors, a measurement sensor (3a) and a reference sensor (3b). 23. System, according to any one of claims 13 to 22, characterized by determining a measurement reference value when measuring reference values when detecting responses in which the radiation spectrum does not pass through the sample (2). 24. System, according to claim 22 or 23, characterized by determining a measurement reference value by measuring reference values by means of the reference sensor (3b) and measuring transmittance values of the sample (2 ) through the measuring sensor (3a) simultaneously. 25. System according to any one of claims 13 to 24, characterized in that the emitted radiation spectrum is a visible light spectrum in the range between 380 nm and 780 nm.