Abstract:
A fiber-optic measuring device for measuring physical quantities, comprising a transducer unit and an electronic unit which are interconnected by means of at least one optic fiber. The measuring transducer unit comprises at least two photoluminescent elements, of which at least one is positioned in the ray path of light from the fiber, at least partly behind another element. The physical quantities to be measured are arranged to influence the light transmission between the photo-luminescent elements. The electronic unit includes at least two light sources having different emission spectra which are so chosen in relation to the absorption and transmission spectra of the photo-luminescent elements that one light source is arranged to excite substantially one of the photo-luminescent elements whereas the other light sources at least partly excite the other element or elements.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a fiber-optic measuring device for measuring a physical quantity, comprising a transducer unit and an electronic unit interconnected by an optic fiber. 
     2. Description of the Prior Art 
     A large number of physical and chemical measurements may be effected using an optical transducer influenced by the quantity to be measured to modulate the light transmission. To transmit the light intensity variations caused by the transmission changes, without degradation of the accuracy of measurement, in a fiber-optic measuring system, systems with wavelength demultiplexing and spectral light division in the transducer have been developed. These measuring systems require a relatively complicated optical system in the transducer unit, while at the same time great demands are placed on the optoelectronics in the measuring electronic unit. 
     Many optical effects, which are well suited for measuring physical quantities, involve a change of the light transmission of a sensor material. To fiber-optically sense these transmission changes with sufficient accuracy for measuring purposes, requires the provision of means for compensating for varying attenuation and light reflection in the optical system. 
     OBJECT OF THE INVENTION 
     One object of this invention is to provide a new type of measuring system, which provides a considerably simpler and cheaper transducer and measuring electronic equipment. 
     SUMMARY OF THE INVENTION 
     A measuring device according to the invention is characterized in that the transducer unit comprises at least two photo-luminescent sensor elements, of which at least one is located in the ray path of the light from the optical fiber, completely or partially behind another element. The physical quantity to be measured is adapted to influence the light transmission between these two sensor elements. The electronic unit includes at least two light sources having separate emission spectra, these emission spectra being so chosen relative to the absorption and emission spectra of the said sensor elements that one light source substantially excites one of said photo-luminescent sensor elements, whereas other light sources also excite other elements or at least substantially excite other elements. Thus, a measuring device according to this invention constitutes a solution to the problems mentioned above and provides a possibility of employing new sensor principles. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention will be exemplified in greater detail, by way of example, with reference to the accompanying drawings, wherein 
     FIG. 1 shows a complete measuring system, 
     FIG. 2 shows graphically the spectral relationships, applied to the opto-components of FIG. 1, 
     FIGS. 3, 4 and 5 show three different sensors for measuring displacement, 
     FIG. 6 shows a sensor for measuring angles and number of revolutions, 
     FIG. 7 shows a sensor for measuring a magnetic field, 
     FIG. 8 shows a sensor for measuring levels, 
     FIG. 9 shows an enlarged portion of the sensor element of FIG. 8, 
     FIG. 10 shows graphically the spectral relationships existing in the system of FIG. 8, 
     FIG. 11 shows an alternative measuring system with only one detector channel, 
     FIG. 12 shows how the sensor of FIG. 11 can be formed, 
     FIG. 13 shows a different embodiment of the measuring device of FIG. 11, 
     FIG. 14 shows a still modified sensor, and 
     FIG. 15 shows the spectral relationships associated with the sensor of FIG. 14. 
    
    
     DESCRIPTION OF PREFERRED EMBODIMENTS 
     In the measuring system shown in FIG. 1, light sources 3 and 7 illuminate luminescent sensor elements 30 and 31 via optic filters 4 and 8, optical branches 9 and 10, a ray divider 11 and an optical fiber 29. Luminescent light generated in the sensor elements is led back through the optical fiber 29 and reaches a pair of photodetectors 20 and 24 via the ray divider 11, optical branches 10 and 18, and optical filters 19 and 23. The light sources are frequency-modulated by means of oscillators 1 and 5 feeding respective amplifiers 2 and 6 and the detector signals are frequency-demodulated by band pass filters 22 and 26. For the AC light from the light sources 3 and 7 to be maintained equal in the fiber 29, part of the light is coupled by the ray divider 11 out to a photodetector 12, the output signal of which is frequency-division demultiplexed by members 14 and 15 for control of the variable amplifier 2 with the aid of a regulator 17 and a difference generator 16. The output signal to a measuring instrument 28 is obtained by forming the quotient, at 27, of the demodulated detector signals. The emission spectra of the light sources 3 and 7 are so chosen, relative to the absorption spectra of the sensor elements 30 and 31, that the element 30 is excited by one of the light sources only and the element 31 is excited by the other light source only (or substantially by this). In this way, the formation of the quotient in 27 will give a measuring signal, which is only dependent on the optical transmission properties of a sensor material 32 interposed between the elements 30 and 31 and forming with those elements, the transducer G. Elements 30 and 31 consist of III-V, II-VI, ternary or quaternary semiconductors. 
     The operation of the measuring system shown in FIG. 1 will become clear by noting the spectral relationships shown in FIG. 2. In FIG. 2, 33 and 34 designate the emission spectra of the light sources 3 and 7; 36 and 39 designate the transmission spectra for the filters 4 and 8; 37 and 40 designate the absorption spectra for the sensor elements 30 and 31; 35 and 42 designate the luminescent spectra for the sensor elements 30 and 31, and 38 and 41 designate the transmission spectra for the filters 19 and 23. When the optical transmission of the sensor material 32 is reduced, both the excitation light to, and the luminescent light from, the element 31 will be attenuated to a greater extent, resulting in the quotient formed at 27 between the luminescent light intensities from 30 and 31 being reduced. The quotient formation guarantees that measurements of the physical quantity affecting the optical transmission of the material 32 will be independent of changes in the attenuation arising in the optical fiber 29 and the wavelength concentration in the transducer G in combination with the optical filters 19 and 23, ensures that measurements are independent of reflections which might arise in the fiber-optical system. 
     The light transmission between the sensor elements 30 and 31 can be modulated by the different physical quantities which it may be desired to measure in a large number of different ways, some of which are exemplified in FIGS. 3-10. 
     With the transducer arrangement as shown in FIG. 3, the light-transmission between the sensor elements 30 and 31 is influenced by a screen 32&#39; which is capable of being moved between the elements 30 and 31, by the quantity to be measured, in the directions of the arrows a, or by causing the sensor element 31 to move in the directions of the arrows b and/or c relative to the optical fiber 29. The luminescent elements 30 and 31 shown in FIG. 3 are built up of epitaxial semiconductor layers 44, 45, 46 and 49, 48, 47, grown on substrates of the elements 30 and 31, respectively. The layers 45 and 48 constitute the luminescent layers, and in the element 30 the substrate has been etched away so that it will not block the excitation light. 
     To obtain a more controlled and possibly parallel ray path between the elements 30 and 31, a lens system can be employed in the manner shown in FIG. 4. So-called &#34;Selfoc&#34; lenses 51 and 52 can advantageously be used and these act to diverge and then converge the light in its passage between the elements 30 and 31. As in the FIG. 3 arrangement parameter measurement can be effected via movements of a screen 32&#39;. 
     FIG. 5 shows an alternative lens system in which the excitation light from the optical fiber 29 is reflected by a dichroic mirror 53 towards the element 31. The mirror 53, which may be an interference filter, allows the luminescent light to pass through it onto a second mirror 54, where the luminescent light is reflected back into the fiber 29. Thus, with this system a horizontal displacement of the mirror 54 in the directions of the arrows d will be able to modulate the light at the luminescence wavelength leaving the element 31. Mirror 53 is, of course, not necessary, but if it is not provided both the excitation light and the luminescent light from the element 31 will be modulated by movements of the mirror 54. 
     If, in the system shown in FIG. 4, the lenses 51 and 52 are provided with screen patterns 55 and 56 as shown in FIG. 6, an angle-sensing transducer and/or a speed-measuring transducer is obtained. Between the lenses 51 and 52 a parallel ray bundle exists and this makes it possible to employ a high screen pattern density despite a relatively large distance between the lenses 51 and 52. The extent to which one lens 51, 52 turns (e.g. in the direction of the arrow e) relative to the other will affect the amplitude of luminescent light entering the fiber 29. 
     The sensor configuration shown in FIG. 4 may also be used in the system shown in FIG. 7, for measuring a magnetic field. In this case a polarizer 57, a body 59 of magneto-optical material and an analyzer 58 are located between the lenses 51 and 52 to form a transducer 60. The magneto-optical material of the body 59 is preferably of domain type, and this has been indicated by representing some domains at 61 in FIG. 7. Changes in the magnetic field applied to the body 59 will influence the amplitude of luminescent light passing back down the optical fiber 29. 
     FIG. 8 shows one example of a level (e.g. a liquid level) measuring system. Light-emitting diodes (LEDs) 71 and 72 feed incident light into a fiber system 73. By the action of optical filters 74 and 75, undesired wavelengths are filtered away from the spectra of the LEDs. In a sensor 76 the incident light is converted into light of a different wavelength by means of photoluminescence. FIG. 9 shows the sensor 76 in greater detail. The incident light is fed through a fiber 94 to a sensor portion 91, which has low absorption to incident light of the wavelength emitted by the LED 72, but high absorption to incident light of the wavelength emitted by the LED 71. An intermediate wavelength structure 93 connects the sensor portion 91 and a sensor portion 92. The sensor portion 92 has high absorption to the incident light emitted by the LED 72. The emission spectra for both the LEDs 71 and 72 and for both the luminescent sensor portions 91 and 92 are shown in FIG. 10, which also shows (at T1) the transmission curve for the sensor portion 91. The light emitted from the two sensor portions 91 and 92 is led through the fiber 94 back into the measuring electronic system and is detected in a detector portion 77 (see FIG. 8). The detector portion 77 comprises a fiber branch 78, two photodiodes 79 and 80, shown used with optical filters 81 and 82 but these filters are not essential. Transmission curves T11 and T12 for these filters are schematically shown by dash lines in FIG. 10. The LEDs 71 and 72 are amplitude-modulated at frequencies f1 and f2, respectively. In FIG. 10, λ designates wavelength and I intensity. Amplifiers 83 and 84 (see FIG. 8) are phase-locked to these frequencies. Thus, an electrical signal S1 is generated by amplifier 83, which is dependent on the luminescence intensity from the sensor portion 91, and a signal S2 is generated by amplifier 84, which, in a corresponding manner, represents the luminescence intensity from the sensor portion 92. When a liquid level in the vicinity of the sensor 91, 92, 93 is at a position A shown in FIG. 9, the quotient S1/S2 assumes a certain given value. This value is determined by the properties of the components included in the system but is maintained constant even in the face of varying attenuation in the system because it is a quotient of the signals S1 and S2 which is monitored. The value of the quotient can also be made to be independent of the temperature by a suitable matching of the material properties of the sensor portions 91 and 92. When the liquid level assumes a position B shown in FIG. 9, the wave conductor properties of the sensor 93 are changed by the fact that the refractive index for the media above and below the liquid surface are not the same. Thus, the value of the quotient S1/S2 is changed. This quotient, therefore, provides a measure of whether or not the liquid level exceeds the level C shown in FIG. 9. 
     For systems employing optic fibers of multimode type, the above principle is best suited for level measuring transducers of the on/off type. If fibers or wave conductor structures of monomode type are used instead however, the coupling of light out of the sensor portion 93 can be accurately controlled. The measuring system is then able to deliver a signal which continuously indicates the position of the liquid level. FIG. 11 shows the sensor portion in such a level device. In this case, the sensor portion 93 is a wave conductor structure of monomode type. FIG. 12 shows the transducer portion of a monostable design. This transducer comprises a GaAs substrate 95, an epitaxial layer 96 of Al X9  Ga 1-X9  As, an epitaxial layer 93 of Al X3  Ga 1-X3  As, an epitaxial layer 91 of Al X1  Ga 1-X1  As, and an additional epitaxial layer 92 of Al X2  Ga 1-X2  As. The doping concentrations and the Al contents in the layers included are chosen so that X9 assumes the greatest value, which provides a wave conductor effect at the &#34;inner&#34; limiting surface of the wave conductor. X3 is chosen so that the absorption of the wavelengths transmitted in the system is small. The values of X1 to X9 are therefore selected so that X9&gt;X3&gt;X1&gt;X2. The sensor portions 91 and 92 are provided with a doping concentration such that luminescent light is generated with good efficiency in these portions. The spectra of the luminescent light thus emitted may have the forms shown at PL1 and PL2 in FIG. 10. 
     One problem that may arise when a measuring device according to the above-described designs is used for level measurement, for example in various liquids, is that the hydraulic and dielectric properties of these liquids may have an effect on the function of the measuring device and on its calibration. It may therefore be convenient to design the measuring device according to the principle shown in FIG. 13. In FIG. 13, it is the boundary surface 100, whose position is to be sensed. Sensor portions 91, 92 and 93, with properties as described above, are enclosed within an inner container 101, containing a liquid shown at 102. The properties of this liquid can thus be chosen freely with this embodiment, irrespective of the liquid defining the surface 100. A flexible diaphragm 103 allows the volume of the container 101 to be varied as the diaphragm 103 is deflected. The extent to which the diaphragm 103 will be deflected is determined by the pressure difference across it and this in turn is influenced by changes in the level 100. By a suitable choice of the volume of the inner container 101 and the thickness and cross-sectional area of the diaphragm 103, the transducer 91, 92, 93 can be given any suitable characteristic for a given application. 
     FIGS. 14 and 15 show a further embodiment of sensor for measuring electrical fields and voltages and its associated spectral relationships. In the same way as in FIG. 3, the transducer comprises two luminescent elements 30 and 31 with the epitaxial layers 44-46 and 47-49, respectively, applied on the substrates 43 and 50. However, the element 30 has a hole 113 etched through the layers 44-46, through which light is able to pass to the element 31 without being influenced by the element 30 (the element 31 is identical with the element 31 in FIG. 3). Instead of a through-hole, the layers 44 and 45 may be etched away whereas the layer 46 is retained. between the elements 30 and 31 an electro-optical modulator 32&#34; is placed, which consists of a polarizer 104, a glass plate 105, a transparent electrode 106, a liquid crystal layer 107, a transparent electrode 108, a glass plate 109 and a polarizer 110. By means of contacts 111 and 112, a voltage U can be applied across the electrodes 105 and 103 for modulating the optical properties of the liquid crystal layer 107. 
     FIG. 15 shows emission spectra 33 and 34 of the two light sources (e.g. the sources 3 and 7 in FIG. 1). In FIG. 15, α is light absorption, L is light emission, T is light transmission, and λ is wavelength. 
     The embodiments described above can be varied in many ways within the scope of the following claims.