The present application claims priority as a national stage application under 35 U.S.C. § 371 to PCT Application No. PCT/EP2020/062848 filed on May 8, 2020, entitled, “Apparatus for Determining a Layer Thickness and Method of Operating such Apparatus,” which claims priority to EP Application No. 19176509.8 filed on May 24, 2019, entitled “Apparatus for Determining a Layer Thickness and Method of Operating such Apparatus,” both of which are incorporated by reference herein.
The disclosure relates to an apparatus for determining a layer thickness of a plurality of layers arranged on a body using Terahertz (THz) radiation. The disclosure further relates to a method of operating an apparatus for determining a layer thickness of a plurality of layers arranged on a body using Terahertz, THz, radiation.
The German Patent Application No. DE102016118905 A1 filed on Oct. 5, 2016 and entitled, “Apparatus and method for time resolved detection of pulsed electromagnetic radio frequency radiation,” discloses an apparatus for measuring THz radiation comprising a distance measurement system.
Embodiments relate to an apparatus for determining a layer thickness of a plurality of layers arranged on a body, wherein said apparatus comprises a Terahertz, THz, transmitter configured to emit a THz signal to said plurality of layers and a THz receiver configured to receive a reflected portion of said THz signal that has been reflected by at least one layer of said plurality of layers, wherein said apparatus is configured to determine a layer thickness of at least one of said plurality of layers based on said reflected portion of said THz signal, wherein said apparatus further comprises a distance measuring device for determining at least one parameter characterizing a distance between said apparatus and said body, wherein said distance measuring device comprises at least one optical triangulation sensor. The optical triangulation sensor enables efficient and yet precise distance measurements and is also suitable for application in comparatively harsh environments such as industrial production lines.
According to further embodiments, said distance measuring device is configured to determine said distance between said apparatus and said body and/or variations of said distance between said apparatus and said body.
According to further embodiments, said distance measuring device is configured to determine said distance and/or said variations of said distance with a predetermined sample rate of at least 1 kilohertz (kHz), or at least 10 kHz, or at least 20 kHz.
According to further embodiments, said distance measuring device comprises two or more optical triangulation sensors.
According to further embodiments, said THz radiation comprises at least one frequency component in the range of 0.3 THz and 100 THz, preferably in the range of 0.5 THz and 10 THz.
According to further embodiments said at least one optical triangulation sensor comprises one light source for illuminating a surface region of said body with optical measurement radiation, wherein said optical measurement radiation particularly comprises laser radiation, and one light detector for receiving a respective reflected portion of said optical measurement radiation which has been reflected by said surface region.
According to further embodiments, said at least one optical triangulation sensor comprises one light source for illuminating a surface region of said body with optical measurement radiation, wherein said optical measurement radiation particularly comprises laser radiation, and at least two light detectors for receiving a respective reflected portion of said optical measurement radiation which has been reflected by said surface region.
According to further embodiments, said at least one optical triangulation sensor comprises a first light source for illuminating a surface region of said body with a first optical measurement radiation and a second light source for illuminating said surface region of said body with a second optical measurement radiation, wherein said first and/or second optical measurement radiation particularly comprises laser radiation, wherein said at least one optical triangulation sensor further comprises at least one light detector for receiving a reflected portion of said first and/or second optical measurement radiation which has been reflected by said surface region.
According to further embodiments said at least one optical triangulation sensor is arranged relative to an optical axis of said apparatus such that said at least one optical triangulation sensor can detect a) at least a diffuse reflection of optical measurement radiation emitted by at least one light source of said at least one optical triangulation sensor and reflected by a surface region of said body, preferably only a diffuse reflection of optical measurement radiation, and/or b) at least a direct reflection of optical measurement radiation emitted by at least one light source of said at least one optical triangulation sensor and reflected by a or said surface region of said body, preferably only a direct reflection of optical measurement radiation.
According to further embodiments, said at least one optical triangulation sensor is configured and arranged relative to an optical axis of said apparatus such that said at least one optical triangulation sensor can selectively detect a) a diffuse reflection of optical measurement radiation emitted by at least one light source of said at least one optical triangulation sensor and reflected by a surface region of said body, whereby a first triangulation path is defined, and/or b) a direct reflection of optical measurement radiation emitted by at least one light source of said at least one optical triangulation sensor and reflected by a or said surface region of said body, whereby a second triangulation path is defined.
According to further embodiments said apparatus is configured to determine a quality measure of said first triangulation path and said second triangulation path, and to select one of said first triangulation path and said second triangulation path depending on said quality measure, wherein said quality measure characterizes a variance and/or noise of a plurality of distance measurements associated with a respective one of said first triangulation path and said second triangulation path. According to further embodiments, said apparatus is configured to determine for said two triangulation paths a direction cosine relative to the surface normal. According to further embodiments, standard deviations of preferably synchronous measurements of said two triangulation paths over a limited time may be used as said signal quality measure.
According to further embodiments said apparatus comprises a laser source, a beam splitter, and an optical delay stage, wherein said THz transmitter comprises a THz source, wherein said THz receiver comprises a THz detector, wherein said laser source is configured to provide a laser signal to said beam splitter, wherein said beam splitter is configured to a) split said laser signal into a first signal and a second signal, b) provide said first signal to said THz source of said THz transmitter, c) provide said second signal to said optical delay stage, wherein said optical delay stage is configured to apply a predetermined time-variable, preferably periodical, delay to said second signal, wherein a delayed signal is obtained, and to provide said delayed signal to said THz detector of said THz receiver.
According to further embodiments, said apparatus is configured to determine a delay parameter, which characterizes an effective delay of said delayed signal taking into account the predetermined time-variable, preferably periodical, delay provided by said optical delay stage and variations of said distance between said apparatus and said body, wherein preferably said apparatus is configured to determine said layer thickness depending on said delay parameter. As an example, according to further embodiments, a time-dependent signal may be determined which characterizes a signal as received by means of said THz detector. Based on this time-dependent signal, the layer thickness of a plurality of layers arranged on a body may be determined. For compensating (undesired) distance variations during the respective THz measurement, the delay parameter may be used, e.g. for correcting and/or “refining” said time-dependent signal, thus eliminating the effect of the (undesired) distance variations. This way, more precise layer thickness measurements are enabled. In other words, according to further embodiments, the layer thickness is not determined directly depending on said delay parameter, but said delay parameter may be used to compensate errors in said time-dependent signal (and/or a time axis thereof), which increases a precision when determining said layer thickness depending on said (compensated) time-dependent signal.
Further embodiments relate to a method of operating an apparatus for determining a layer thickness of a plurality of layers arranged on a body, wherein said apparatus comprises a THz transmitter configured to emit a THz signal to said plurality of layers and a THz receiver configured to receive a reflected portion of said THz signal that has been reflected by at least one layer of said plurality of layers, wherein said apparatus is configured to determine a layer thickness of at least one of said plurality of layers based on said reflected portion of said THz signal, wherein said apparatus further comprises a distance measuring device for determining at least one parameter characterizing a distance between said apparatus and said body, wherein said distance measuring device comprises at least one optical triangulation sensor, wherein said method comprises: determining said at least one parameter characterizing the distance between said apparatus and said body, determining said layer thickness of said at least one of said plurality of layers depending on said at least one parameter.
According to further embodiments, said measuring device comprises two or more optical triangulation sensors, wherein preferably said two or more optical triangulation sensors are selectively and/or simultaneously used.
According to further embodiments, said at least one optical triangulation sensor comprises one light source for illuminating a surface region of said body with optical measurement radiation, wherein said optical measurement radiation particularly comprises laser radiation, and at least two light detectors for receiving a respective reflected portion of said optical measurement radiation which has been reflected by said surface region, wherein said method further comprises selecting one or more of said at least two light detectors for performing a distance measurement.
According to further embodiments, said at least one optical triangulation sensor comprises a first light source for illuminating a surface region of said body with a first optical measurement radiation and a second light source for illuminating said surface region of said body with a second optical measurement radiation, wherein said first and/or second optical measurement radiation particularly comprises laser radiation, wherein said at least one optical triangulation sensor further comprises at least one light detector for receiving a reflected portion of said first and/or second optical measurement radiation which has been reflected by said surface region, wherein said method further comprises selecting one or more of said at least two light sources for performing a distance measurement.
According to further embodiments, said at least one optical triangulation sensor is configured and arranged relative to an optical axis of said apparatus such that said at least one optical triangulation sensor can selectively detect a) a diffuse reflection of optical measurement radiation emitted by at least one light source of said at least one optical triangulation sensor and reflected by a surface region of said body, whereby a first triangulation path is defined, and/or b) a direct reflection of optical measurement radiation emitted by at least one light source of said at least one optical triangulation sensor and reflected by a or said surface region of said body, whereby a second triangulation path is defined, wherein said method further comprises selectively using the first triangulation path or the second triangulation path or both the first triangulation path and the second triangulation path, wherein preferably said apparatus determines a quality measure of said first triangulation path and said second triangulation path and selects one of said first triangulation path and said second triangulation path depending on said quality measure, wherein preferably said quality measure characterizes a variance and/or noise of a plurality of distance measurements associated with a respective one of said first triangulation path and said second triangulation path.
According to further embodiments, said apparatus comprises a laser source, a beam splitter, and an optical delay stage, wherein said THz transmitter comprises a THz source, wherein said THz receiver comprises a THz detector, wherein said laser source provides a laser signal to said beam splitter, wherein said beam splitter a) splits said laser signal into a first signal and a second signal, b) provides said first signal to said THz source of said THz transmitter, c) provides said second signal to said optical delay stage, wherein said optical delay stage applies a predetermined time-variable, preferably periodical, delay to said second signal, wherein a delayed signal is obtained, and provides said delayed signal to said THz detector of said THz receiver.
According to further embodiments, said apparatus determines a delay parameter, which characterizes an effective delay of said delayed signal taking into account the predetermined time-variable, preferably periodical, delay provided by said optical delay stage and variations of said distance between said apparatus and said body, wherein preferably said apparatus determines said layer thickness depending on said delay parameter.
Further embodiments relate to a use of the apparatus according to the embodiments and/or the method according to the embodiments for determining layer thicknesses of a plurality of layers arranged on a surface of a body, wherein preferably said body and/or said surface of said body is electrically conductive, wherein preferably a top layer of said plurality of layers comprises a clear coat, and wherein preferably a second layer, which is adjacent to said top layer, comprises a base coat. According to further embodiments, said surface of said body is not electrically conductive.
Further features, aspects and advantages of the embodiments are given in the following detailed description with reference to the drawings in which:
The apparatus 100 (
According to further embodiments, said THz radiation TS comprises at least one frequency component in the range of 0.3 THz and 100 THz, preferably in the range of 0.5 THz and 10 THz.
The apparatus 100 (
The apparatus 100 further comprises a distance measuring device 130 for determining at least one parameter P1 characterizing a distance d between said apparatus 100 and said body 10, wherein said distance measuring device 130 comprises at least one optical triangulation sensor 132. The optical triangulation sensor 132 enables efficient and yet precise distance measurements and is also suitable for application in comparatively harsh environments such as industrial production lines. Preferably, the distance measuring device 130 or at least one component of it is also arranged in and/or attached to said common housing 102.
According to further embodiments, a control device 103 may be provided to control an operation of the apparatus 100 or at least one component 110, 120, 130 thereof.
According to further embodiments, cf. the apparatus 100a of
According to further embodiments, cf.
According to further embodiments, the optical triangulation sensor 132a is configured to determine the distance d (
According to further embodiments, said at least one optical triangulation sensor 132a is arranged relative to an optical axis OA (
According to further embodiments, cf.
According to further embodiments, cf.
According to further embodiments, cf.
According to further embodiments, said at least one optical triangulation sensor 132c, 132d is configured and arranged relative to an optical axis OA of said apparatus 100, 100a such that said at least one optical triangulation sensor 132c, 132d can selectively detect a) a diffuse reflection of optical measurement radiation MR emitted by at least one light source 1320, 1320a, 1320b of said at least one optical triangulation sensor and reflected by a surface region 10a′ of said body 10, whereby a first triangulation path is defined, and/or b) a direct reflection of optical measurement radiation emitted by at least one light source 1320, 1320a, 1320b of said at least one optical triangulation sensor and reflected by said surface region 10a′ of said body 10, whereby a second triangulation path is defined. Particularly the exemplary configurations of
As an example, for illustrative purposes, the first triangulation path ((at least primarily) diffuse reflection case) may be considered to comprise e.g. arrows MR, RMR2 of
According to further embodiments, a diffuse reflection may be obtained if the surface normal SN of the surface 10a to be measured is not within a triangulation plane defined by e.g. the arrows MR, RMR (
According to further embodiments, at least one of said light sources and/or light detectors of at least one optical triangulation sensor (and/or at least one component thereof) may be movable, particularly rotatable, preferably around the focal point FP of the THz radiation on the surface 10a, to control diffuse and/or direct reflections for measurement.
According to further embodiments, a diffuse reflection of measurement radiation MR may be obtained if the surface normal SN of the surface 10a to be measured is within the triangulation plane defined by e.g. the arrows MR, RMR (
According to further embodiments, a diffuse reflection of measurement radiation MR may be obtained if the surface normal SN of the surface 10a to be measured is not within the triangulation plane defined by e.g. the arrows MR, RMR (
According to further embodiments, whether or not the surface normal SN of the surface 10a to be measured is within a triangulation plane may be controlled by positioning the measuring head 102 relative to the surface normal SN and hence the body 10.
According to further embodiments, a symmetric arrangement of the optical axes of elements 1320, 1321 with respect to the optical axis OA of the measuring head 102 (e.g., same angles between respective optical axis of elements 1320, 1321 and the optical axis OA) may e.g. be attained by design, e.g. by symmetrically arranging elements 1320, 1321 with respect to the measuring head 102 or its (other) components 110, 120. Similarly, according to further embodiments, an asymmetric arrangement may be attained, e.g. by asymmetrically arranging elements 1320, 1321 (and/or other elements) with respect to the measuring head 102 or its (other) components 110, 120.
According to further embodiments, a diffuse reflection of measurement radiation MR, MR1, MR2 is used for matte surfaces 10a to slightly scattering surfaces 10a.
According to further embodiments, a direct reflection of measurement radiation MR may be obtained if the surface normal SN of the surface 10a to be measured is within the triangulation plane defined by e.g. the arrows MR, RMR (
According to further embodiments, a direct reflection of measurement radiation MR, MR1, MR2 is used for glossy surfaces 10a to slightly scattering surfaces 10a.
According to further embodiments, more than two light sources per sensor and/or more than two detectors per sensor are also possible, wherein further degrees of freedom for distance measurement may be provided. This way, a reliable and precise distance measurement is enabled according to further embodiments, which is substantially independent e.g. of surface properties of the layers 11, 12, 13 such as glossy and/or matte surfaces and the like.
According to further embodiments, one or more light sources per sensor and/or more than two detectors per sensor may be provided, and/or more than one light source and at least one detector. Said light source(s) and detectors(s) may be positioned and arranged such relative to each other that a plurality of triangulation paths is defined, wherein at least one triangulation path enables to perform a distance measurement based on evaluation of a direct reflection of measurement radiation, and wherein at least one further triangulation path enables to perform a distance measurement based on evaluation of a diffuse reflection of measurement radiation. According to further embodiments, at least one of said triangulation paths may be dynamically (i.e., during operation of said apparatus) selected for one or more distance measurements.
According to further embodiments, cf. the flow chart of
According to further embodiments, the steps 220, 222 according to
According to further embodiments, at least one layer thickness of at least one layer arranged on said object 10′ may be measured at a plurality of measuring points of a surface 10a (
According to further embodiments, cf.
According to further embodiments, one or more of the components 1002, 1004, 1006, 1006a, 1008, 112, 122 may also be provided in the THz measuring head 102 according to
According to further embodiments, said THz source 112 may comprise a photoconductive switch (not shown) which may generate said THz signal TS in response to receiving said first signal s1 from the laser source 1002. A direct current (DC) bias voltage may be provided to said photoconductive switch but is not depicted in
According to further embodiments, said THz detector 122 may be configured to receive said reflected portion TSR of said THz signal TS and to generate an electric output signal es characterizing said reflected portion TSR when receiving the delayed signal s2′, preferably in the form of a plurality of comparatively short (in comparison with a duration of said received reflected portion TSR of said THz signal TS) laser pulses. This way, the delayed laser signal s2′ “probes” the reflected portion TSR of said THz signal TS as received by the detector 122.
According to further embodiments, said THz detector 122 may also comprise a photoconductive switch (e.g., similar to the photoconductive switch of the THz source 112), in which free charge carriers are generated when said reflected portion TSR of said THz signal TS is received by the detector and when said detector 122 is (simultaneously) illuminated with said delayed signal s2′. By applying a DC bias voltage to said detector 122, an electric current, resulting from said generated free charge carriers, may be obtained at the detector 122, which may e.g. form the electric output signal es. Alternatively, according to further embodiments, an electric voltage characterizing said electric current, may be used as said output signal es. According to further embodiments, an amplifier (not shown) may be used to provide an output voltage es characterizing said current provided by the photoconductive switch of the detector 122.
In other words, said electric output signal es is proportional to an instantaneous electric field of the received reflected portion TSR of said THz signal TS. This way, by irradiating the photoconductive switch of the detector 122 with a plurality of comparatively short (in comparison with a duration of said received reflected portion TSR of said THz signal TS) laser pulses in form of said delayed signal s2′, the received reflected portion TSR may be sampled or probed, respectively. By varying the delay of said delayed signal s2′, e.g. by controlling the optical delay stage 1006, for different impulses of said delayed signal s2′, different portions of the received reflected portion TSR of said THz signal TS may be sampled, whereby a time-resolved sampled signal characterizing said received reflected portion TSR is obtained.
According to further embodiments, the electric output signal es is sampled with a first sample rate of e.g. 200 kilohertz (kHz), whereby a sampled signal is obtained which is a time-discrete and value discrete representation of said reflected portion TSR of said THz signal TS as received by the detector 122, e.g. of the electric field associated with said reflected portion TSR of said THz signal TS as received by the detector 122.
In this regard, curve C1 of
According to further embodiments, the sampling and/or further processing of said sampled signal, cf. e.g. curve C1 of
According to further embodiments, the layer thickness measurements of the layers 11, 12, 13 (
According to further embodiments, said optical delay stage 1006, cf.
By periodically moving said corner reflector 1006a along the coordinate axis x, said predetermined time-variable, preferably periodical, delay may be applied to said second signal s2, which enables to sample the received reflected portion TSR of said THz signal TS in a time-resolved manner, as mentioned above.
According to further embodiments, a position and/or movement of said corner reflector 1006a may be controlled by said control device 103. Preferably, according to further embodiments, said position and/or movement of said corner reflector 1006a may be synchronized with a generation of pulses of said THz signal TS and/or with the operation of the laser source 1002.
According to further embodiments, said corner reflector 1006a is periodically moved between two end points (not shown) along said coordinate axis x. For this purpose, a translation stage (not shown) and/or any other suitable (e.g., linear) drive for driving said movement of said corner reflector 1006a may be provided. Said drive may e.g. be controlled by the control device 103.
In
According to further embodiments, a THz time base t1′, cf. curve C3 of
According to further embodiments, said THz time base t1′ may be used to map the sampled signal C1 (
According to further embodiments, the signal represented by curve C4′ may be employed to determine the layer thickness of one or more of said layers 11, 12, 13 on said body 10.
The embodiments explained above with reference to
If, however, according to further embodiments, vibrations are present, which is expected for a real application of e.g. the measuring head 102 mounted to a positioning system 104 (
To address potential vibrations, according to further embodiments, the apparatus 100, 100a, 100b is configured to determine a delay parameter, which characterizes an effective delay of said delayed signal s2′ (
In other words, according to further embodiments, a variation in time of said distance d between the devices 110, 120, 130 and the body 10 is taken into consideration when determining said layer thicknesses. Advantageously, said variation in time of said distance d may be considered in the form of said delay parameter, which enables a combined processing of two effects that may influence a precision of layer thickness measurement: a) the delay as introduced by optical delay stage 1006, which is desired as it enables to attain a sampled, i.e. time-resolved signal shape of the electrical field of a reflected portion TSR of a THz signal or pulse TS, and b) the delay as introduced by vibrations, which is usually undesired as it affects precision.
According to further embodiments, the apparatus 100 performs distance measurements, e.g. by using said distance measuring device 130, wherein preferably distance measurements are performed with a rate of 1 kHz (kilohertz) or greater, preferably 10 kHz or greater, e.g. 20 kHz. Further preferably, said distance measurements are synchronized with an emission of said THz signal TS and/or a reception of said reflected portion TSR. This way, variations in distance between the devices 110, 120, 130 and the body 10 may be determined and may be taken into consideration for layer thickness measurement. According to further embodiments, and as already mentioned above, prior to performing said distance measurements, said apparatus may first determine a suitable triangulation path for said distance measurements, e.g. depending on the quality measure QM as explained above with reference to
As an example, curve C5 of
In
According to further embodiments, said variations C7 may be derived from measurements of said (absolute) distanced (
According to further embodiments, a correction of an associated time axis may be performed depending on the first parameter P1 and/or the second parameter P2, wherein either the first parameter P1 or the second parameter P2 may be chosen, i.e. depending on the respective quality measure QM of the associated triangulation path.
According to further embodiments, an effective elongation of said corner reflector 1006a is determined based on the actual elongation of said corner reflector 1006a, c.f. curve C6 of
According to further embodiments, if different time bases are used for curves C6, C7, at least one of said curves C6, C7 may be adapted to the other curve, e.g. by interpolation or decimation.
According to further embodiments, the effective elongation C8 of the corner reflector 1006a may represent and/or may be used as said abovementioned delay parameter, which characterizes an effective delay of said delayed signal s2′ (
According to further embodiments, a THz time base t1′, cf. curve C9 of
According to further embodiments, said THz time base t1′, cf. curve C9 of
For comparison,
The embodiments explained above with reference to
According to further embodiments, said apparatus 100, 100a, 100b is configured to determine said delay parameter, cf. e.g. curve C8 of
According to further embodiments, the apparatus according to the embodiments may advantageously be used with robots 104 (
According to further embodiments, any configuration (or combinations) of the distance measuring device 130 according to the embodiments (e.g. according to
According to further embodiments, the distance measuring device 130 may be configured to determine said distance d with a predetermined measurement rate of e.g. 1 kHz, preferably 10 kHz or 20 kHz. According to further embodiments, the distance measuring device 130 and/or the control device 103 may determine a variation C7 (
Further, in step 234, also the effective elongation C8 (
In step 236 (
According to further embodiments, at least some of the steps 230, 232, 234, 236 or sub-steps thereof may also be performed at least partially overlapping or simultaneously. As an example, the determination of said distance d and the determination of said shaker elongation may be performed simultaneously or quasi-simultaneously.
According to further embodiments, the control device 1030 comprises at least one calculating unit 1032, at least one memory unit 1034 associated with (i.e., usably by) the at least one calculating unit 1032 for at least temporarily storing a computer program PRG, wherein said computer program PRG is configured to at least temporarily control an operation of said control device 1030 and/or said apparatus 100 and/or at least one component 104, 110, 120, 130 of said apparatus 100. According to further embodiments, the computer program PRG is configured to perform the method according to the embodiments.
According to further embodiments, the calculating unit 1032 comprises at least one of the following elements: a microprocessor, a microcontroller, a digital signal processor (DSP), a programmable logic element (e.g., FPGA, field programmable gate array), an ASIC (application specific integrated circuit), hardware circuitry. According to further embodiments, any combination of two or more of these elements is also possible.
According to further embodiments, the memory unit 1034 comprises at least one of the following elements: a volatile memory 1034a, particularly a random-access memory (RAM), a non-volatile memory 1034b, particularly a Flash-EEPROM. Preferably, said computer program PRG is stored in said non-volatile memory 1034b.
According to further embodiments, the control device 1030 comprises a first interface 1036 enabling data communication D1 with and/or control of the THz transmitter 110 and/or the THz receiver 120 and/or the distance measuring device 130.
Further embodiments relate to a use of the apparatus according to the embodiments and/or the method according to the embodiments for determining layer thicknesses of a plurality of layers arranged on a surface of a body, wherein preferably said body and/or said surface of said body may be electrically conductive or may comprise a dielectric material, wherein preferably a top layer of said plurality of layers comprises a clear coat, and wherein preferably a second layer, which is adjacent to said top layer, comprises a base coat. As an example, said body may represent a part of a vehicle such as a car, and said plurality of layers may comprise paint layers.
The principle according to preferred embodiments enables to precisely determine the distance d and/or variations of said distance d, so that precise THz-signal based layer thickness measurements may be performed, wherein the determination of said layer thickness may be made taking into consideration said distance d and/or variations of said distance d. Particularly, at least some of the abovementioned preferred embodiments may at least temporarily offer at least one of the following advantages: a) high precision, e.g. down to a sub-μm (micrometer) range, b) angular displacements e.g. between an optical axis of the optical triangulation sensor(s) and the optical axis of the THz measurement head 102, of up to 1° (degree) may be tolerated, c) large operational range with respect to distance measurements (e.g., +/−10 mm), d) suitable for comparatively large values of said distance d to the body 10 (
According to further embodiments, it is also possible to employ one or more distance measuring devices other than optical triangulation sensors. According to further embodiments, one or more distance measuring devices based on at least one of the following measurement principle may also be used, alternatively or additionally to the optical triangulation sensors: electric distance measuring devices, acoustic distance measuring devices, optical distance measuring devices other than optical triangulation sensors.
Number | Date | Country | Kind |
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19176509 | May 2019 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/062848 | 5/8/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/239391 | 12/3/2020 | WO | A |
Number | Name | Date | Kind |
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10408767 | Pearcey | Sep 2019 | B1 |
20100195090 | Ohtake | Aug 2010 | A1 |
20130003038 | Tachizaki | Jan 2013 | A1 |
20190259108 | Bongartz | Aug 2019 | A1 |
20200240909 | Maas | Jul 2020 | A1 |
Number | Date | Country |
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2019073074 | Apr 2019 | WO |
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20220205777 A1 | Jun 2022 | US |