This application is based upon and claims the benefit of priority from British Patent Application No. GB 1718699.0, filed on 13 Nov. 2017, the entire contents of which are incorporated by reference.
This disclosure concerns apparatus for use in measuring surface roughness by angular speckle correlation.
Angular speckle correlation is a non-contact measurement technique that allows the roughness of a surface to be evaluated. The technique involves obtaining two speckle patterns by illuminating the same surface with coherent light under two different angles of incidence. The degree of correlation between the speckle patterns, for a fixed difference in angle of incidence, is proportional to the mean roughness Ra and the RMS roughness Rq of the surface.
The technique may be easily validated experimentally by use of standard equipment on an optical bench. However, a demand exists for use of non-contact measurement techniques in, for example, production line and service situations, along with means of measuring surface roughness of components with no line of sight thereto.
The invention is directed towards apparatus and systems for use in the measurement surface roughness by angular speckle correlation.
In one aspect, an imaging probe is provided. The imaging probe comprises a first illumination fibre to illuminate a sample location on a surface, and having an input end for coupling of coherent light into the fibre, and an output end cleaved at an angle θ1, and a second illumination fibre to illuminate the sample location on the surface, and having an input end for coupling of coherent light into the fibre, and an output end cleaved at an angle θ2 that is less than θ1. The imaging probe also comprises an image transmission system for imaging a speckle pattern caused by illumination of the sample location on the surface by coherent light from either the first illumination fibre or the second illumination fibre.
In another aspect, an imaging system is provided. The system comprises a coherent light source configured to produce coherent light. A first illumination fibre is included to illuminate a sample location on a surface, and having an input end for coupling of the coherent light into the fibre, and an output end cleaved at an angle θ1. A second illumination fibre is included to illuminate the sample location on the surface, and having an input end for coupling of coherent light into the fibre, and an output end cleaved at an angle θ2 that is different from θ1. An image transmission system is included for imaging a speckle pattern caused by illumination of the sample location on the surface by coherent light from the first illumination fibre or the second illumination fibre, along with an imaging device configured to capture an image of light that exits the imaging fibre bundle.
Embodiments will now be described by way of example only with reference to the accompanying drawings, which are purely schematic, and not to scale, and in which:
A measurement system 101 for use in measuring surface roughness by angular speckle correlation is shown in
The measurement system 101 comprises an imaging probe 102. As will be described further with reference to
In order to perform angular speckle correlation, the imaging probe is coupled to a source of coherent light, which in this case is a laser 105, along with an imaging device to capture an image of the light exiting the image transmission system, which in this case is a camera 106.
In the present embodiment, the laser 105 is a helium neon laser having a 632.8 nanometre wavelength and a power of 20 milliwatts. It will be appreciated however that other laser specifications and types may be employed, as angular speckle correlation has been shown to work with a large range of laser sources.
In the present embodiment, the coherent light from the laser 105 forms a speckle pattern due to its interaction with surface geometry at the sample location. The speckle pattern is imaged by the imaging fibre bundle which conveys it to the camera 106.
The camera 106 in the present embodiment comprises a monochrome CCD imaging sensor having a 1.3 megapixel resolution. The camera 105 may alternatively comprise a different imaging sensor type, such as a colour sensor, a CMOS sensor, and/or a higher or lower resolution. The camera further comprises in this example a lens for focussing the speckle pattern conveyed by the imaging fibre bundle onto the imaging sensor.
Image processing is performed by a personal computer 107 connected to the camera 106. The overall process of determining the roughness of the sample location 103 will be described with reference to
A cutaway view of the imaging probe 102 is shown in
The imaging probe 102 includes a first illumination fibre 201 and a second illumination fibre 202. In an embodiment, the first illumination fibre 201 and the second illumination fibre 202 are single mode fibres. This may aid in reducing transmission loss, and may allow the probe to have a smaller overall diameter. Multi-mode fibres may still be used, however, depending upon the requirements of the measurement system 101.
In a specific embodiment, the first illumination fibre 201 and the second illumination fibre 202 each have 125 micrometre diameter cores.
As described previously, coherent light from the laser 105 is in use coupled into one of the fibres. In the present embodiment, this is achieved by use of an optical switching device, which in this case is a moveable mirror 203 configured to couple coherent light from the laser 105 into the input end of either the first illumination fibre 201, or the input end of either the second illumination fibre 202. This allows the sample location 103 to either be illuminated by the coherent light from laser 105 via the first illumination fibre 201 or the second illumination fibre 202.
As described previously, angular speckle correlation involves illuminating from two different angles of incidence. Referring to
The fibre cleaving angles θ1 and θ2 are selected based the desired angle of incidence φ1, φ2 and probe working distance dw.
In an embodiment, angle φ1 is 10 degrees. In an embodiment, the difference δφ is from 1 to 2 degrees. In the present embodiment, this therefore means that angle φ2 is from 11 to 12 degrees.
Other angles may be selected depending upon the target application of the probe.
Referring again to
The speckle patterns produced due to the illumination of sample location 103 are in the form of light reflected from the sample location 103. This light is transmitted back to camera 106 by an image transmission system, which in this embodiment comprises an imaging fibre bundle 204. In the present embodiment, the imaging fibre bundle 204 comprises a plurality of fibre cores arranged coherently so as to ensure image integrity. In the present embodiment, the bundle contains 10000 cores, although it will be appreciated that a smaller or greater number could be used depending upon the required resolution.
In the present example, the light is coupled into the imaging fibre bundle 204 by a lens system 205. In the present example, the lens system has a focal length f that provides field of view sufficient to image the totality of the speckle patterns. In a specific embodiment, the lens system 205 comprises a single objective lens. Alternatively, the lens system 205 may comprise a plurality of lenses. In an alternative embodiment, the lens system 205 may be a microlens array.
In this embodiment, the imaging probe 102 further comprises a sheath 206 for containing and protecting the fibres. The sheath may be made from stainless steel. The sheath may be made from rubber. Alternatively, any suitable protective material may be used to form the sheath.
An alternative imaging probe 501 is shown in
In order to achieve this functionality, the imaging probe 501 comprises—in addition to a first illumination fibre 503, a second illumination fibre 504, an imaging fibre bundle 505, and a lens system 506—an optical prism 507. The optical prism 507 is configured to redirect light exiting the first illumination fibre 502 and the second illumination fibre 503. In the present embodiment, the optical prism 507 is a right-angled prism and so coherent light from the illumination fibres is deflected through 90 degrees by total internal reflection. Other prism configurations and thus angles may be used depending upon the requirements of the probe. It is therefore also configured to direct light entering it from the sample location 502 such that it is coupled into the imaging fibre bundle 505 by the lens system 506.
It is envisaged that the functionality of optical prism 507 may alternatively be provided by a mirror system, for example.
A flow diagram illustrating a method of measuring surface roughness using the measurement system 101 is shown in
At step 601, the imaging probe 102 (or 501) is positioned in the appropriate place. In the present example, this involves, with imaging probe 102, positioning it such that the tip of the probe 102 is perpendicular to the sample location 103 and at working distance dw therefrom. The laser 105 is then activated at step 602.
At step 603, the optical switching device is switched to the first illumination fibre. In the present example, therefore, the moveable mirror 203 is moved such that coherent light from the laser 105 is coupled into the first illumination fibre 201.
At step 604, the speckle pattern P1 caused by illumination of the sample location 103 by coherent light from the first illumination fibre 201 is imaged by the camera 106. The speckle pattern P1 may then be transferred to storage in personal computer 107.
At step 605, the optical switching device is switched to the second illumination fibre. In the present example, therefore, the moveable mirror 203 is moved such that coherent light from the laser 105 is coupled into the second illumination fibre 202.
At step 606, the speckle pattern P2 caused by illumination of the sample location 103 by coherent light from the second illumination fibre 202 is imaged by the camera 106. The speckle pattern P2 may then be transferred to storage in personal computer 107.
The correlation between P1 and P2 is then evaluated at step 607. In the present example, this evaluation is performed by personal computer 107.
The angular speckle correlation γ12 between the two speckle patterns P1 and P2 imaged at a location (ξ,η) in the Fourier plane is evaluated using the relation:
At step 608, this value is converted into roughness measures. The angular speckle correlation γ12 is related to the RMS roughness of a surface Rq as follows:
γ12=exp(−Rq2k2δφ2 sin2 φ1) [Equation 2]
in which φ1 is the angle of incidence of light from the first illumination fibre 201, δφ is the change of angle of incidence between the first and second illumination fibres 201 and 202, k=2π/λ is the propagation constant of the coherent light having wavelength λ.
The mean roughness of the surface Ra may additionally be evaluated by using the relation:
As the wavelength λ of laser 105 remains fixed, as do the angle of incidence φ and difference in angle of incidence δφ, it is possible to efficiently derive values for the mean roughness of the surface Ra the RMS roughness of a surface Rq at sample location 103.
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Number | Date | Country | |
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20190145755 A1 | May 2019 | US |