Physical model testing forms a critical part of the development process for offshore renewable energy (ORE) technologies. Devices and structures generally follow a Technology Readiness Level (TRL) development pathway which has nine steps ranging from the initial idea (TRL1) to commercialisation (TRL9). In ORE, technologies are tested extensively in laboratory environments up to TRL4 after which a decision is made as to whether a particular technology has sufficient potential to justify moving to open sea environments where the costs can be much higher. Therefore, physical model testing plays a critical role in the development process and in recent years increased emphasis has been placed on improving quality procedures and implementing best practice methodologies. The International Towing Tank Conference (ITTC) and the International Electrotechnical Commission (IEC) have been developing testing standards whilst European Union funded projects such as Equimar, MaRINET and MaRINET2 have been working with testing infrastructures in developing a more uniform approach to testing. However, a standardised approach to the assessment of uncertainty in physical testing has yet to emerge. This paper focuses on and estimates the variation associated with wave elevation measurements using conductive wave probes in a hydraulics laboratory, a key input in all physical testing analysis

Buret, Benoit

Desmond, Cian

Murphy, Jimmy

Pakrashi, Vikram

Shanley, Matthew

Cork Open Research Archive

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Thanks!Title The assessment of water surface elevation uncertainty in a hydraulicslaboratoryAuthor(s) Desmond, Cian; Buret, Benoit; Shanley, Matthew; Murphy, Jimmy;Pakrashi, VikramPublication date 2019-05Original citation Desmond, C., Buret, B., Shanley, M., Murphy, J. and Pakrashi, V.(2019) ‘The assessment of water surface elevation uncertainty in ahydraulics laboratory’, 13th International Conference on Applications ofStatistics and Probability in Civil Engineering (ICASP13), Seoul, SouthKorea, May 26-30, pp. 1642-1648. doi: 10.22725/ICASP13.324Type of publication Conference itemLink to publisher'sversionhttp://s-space.snu.ac.kr/bitstream/10371/153563/1/324.pdfhttp://dx.doi.org/10.22725/ICASP13.324Access to the full text of the published version may require asubscription.Rights © 2019, the Authors.Item downloadedfromhttp://hdl.handle.net/10468/9989Downloaded on 2020-05-26T23:57:37Z13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  1 The Assessment of Water Surface Elevation Uncertainty in a Hydraulics Laboratory   Cian Desmond MaREI Centre, University College Cork, Cork, Ireland. Benoit Buret MaREI Centre, University College Cork, Cork, Ireland. Matthew Shanley MaREI Centre, University College Cork, Cork, Ireland. Jimmy Murphy MaREI Centre, University College Cork, Cork, Ireland. Vikram Pakrashi Dynamical Systems and Risk Laboratory, School of Mechanical and Materials Engineering, University College Dublin, Ireland; and MaREI Centre, University College Dublin, Dublin, Ireland. ABSTRACT: Physical model testing forms a critical part of the development process for offshore renewable energy (ORE) technologies.  Devices and structures generally follow a Technology Readiness Level (TRL) development pathway which has nine steps ranging from the initial idea (TRL1) to commercialisation (TRL9). In ORE, technologies are tested extensively in laboratory environments up to TRL4 after which a decision is made as to whether a particular technology has sufficient potential to justify moving to open sea environments where the costs can be much higher. Therefore, physical model testing plays a critical role in the development process and in recent years increased emphasis has been placed on improving quality procedures and implementing best practice methodologies. The International Towing Tank Conference (ITTC) and the International Electrotechnical Commission (IEC) have been developing testing standards whilst European Union funded projects such as Equimar, MaRINET and MaRINET2 have been working with testing infrastructures in developing a more uniform approach to testing. However, a standardised approach to the assessment of uncertainty in physical testing has yet to emerge. This paper focuses on and estimates the variation associated with wave elevation measurements using conductive wave probes in a hydraulics laboratory, a key input in all physical testing analysis.  1. INTRODUCTION With the installation of the 30MW Hywind pilot project in 2017 and the ongoing works on the 50MW Kincardine farm, Scotland, Floating Offshore Wind Turbines (FOWT) are now a commercial reality. However, many floating wind platform concepts are still progressing through the Technology Readiness Levels (TRLs) via a combination of experimental and physical testing, over 30 such concepts have been identified [1]. The progression of these technologies through the TRLs has resulted in wealth of fundamental research in the area of floating wind energy to support the advancement to commercialisation. The systematic assessment of experimental uncertainty   has only emerged in the past 15 years [2]. Guidelines are provided for the assessment of uncertainty in tank testing by both ASME [3] and the ITTC [4] with specific guidance provided by 13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  2 the ITTC [5] for the testing of offshore wind turbines. However, these do not provide a systemic approach to the assessment of experimental uncertainty or variation. There have been several recent studies on developing output-only markers for monitoring scaled renewable energy device platforms [8-10], assessing control efficiency [11-13] and even understanding the variations of responses of such scaled structures for various sensors [14]. While these results are important in terms of establishing an experimental benchmark, their results are also fundamentally dependent on the variation and uncertainty of the wave heights generated in the basin. There have been some limited and excellent work around addressing this uncertainty and error [15-17], but there is still a need to experimentally expand this topic further due to the overall paucity of literature in this topic. This paper takes this need of contributing to the experimental evidence base of such variation from wave basin tests and focuses on the assessment of uncertainty in the measurement of wave elevation using conductive wave probes during physical test campaigns. Accurate wave elevation data is vital for all analysis emanating from physical testing. The data used in this report are from an experimental campaign conducted in the Lir National Ocean Test Facility, in the ERI MaREI Centre, University College Cork. A total of six conductive waves probes were used to measure the water elevation. For each probe, a linear regression analysis has been investigated, as well as the uncertainty of the wave probe signal. The results are expected to be helpful for establishing better the Technological Readiness Levels (TRLs) of the various Offshore Renewable Energy (ORE) device concepts. 2. TEST CONDITIONS 2.1. Deep ocean basin specifications The basin shown in Figure 1 below has dimension of 35 m long, 12 m wide and 3 m deep. The basin is equipped with 16 hinged force feedback paddle capable of a peak wave generation condition of the significant wave height Hs =0.6m, peak period Tp =2.7s and the maximum wave height Hmax =1.1m. The water depth can be adjusted thanks to movable floor until the maximum of 3m deep. During the wave probe calibration, the paddles were stationary and the water depth was set at 750 mm to access to adjust the wave probe elevation.   Figure 1: Schematic view of the Lir National Ocean Test Facility: Deep Ocean Basin 2.2. Wave probe specifications The wave probes are resistance probes which output voltage which is directly related to the water surface elevation. During calibration the wave probes were spaced as per Table 1, the first wave probe (WP1) was closest to the paddles and the sixth (WP6) is the one nearest to the beach.   Table 1: Wave probe spacing for experiments. Wave Probe WP1 WP2 WP3 WP4 WP5 WP6 Distance to the WP1 (m) 0.00 0.15 0.28 0.57 1.16 2.44 2.3. Calibration The calibration methodology for the wave probes consists of raising and lowering in still water at set elevations and recording the output voltage for each elevation. The elevations listed in Table 2 were used. For each wave probe, the voltage at each elevation were recorded. Having recorded these data, the linearity of the elevation to voltage relationships were assessed.      13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  3 Table 2. Recorded elevations during a wave probe calibration. Elevation recorded (mm) 0  -300 -200  -100 0 100 3. ANALYSIS METHODS Figure 2 shows a typical signal recorded during a wave probe calibration. To determine the average value at a constant elevation, ranges were determined to calculate the mean voltage signal at each elevation. In order to avoid errors, a period when the disturbances to the water surface elevation caused by the adjustment of the wave probes were selected. A minimum of 90 second was required to calculate the mean of the signal.   Figure 2: WP1 calibration signal 3.1. Linear regression analysis With all mean values for each elevation for each probes, a linear regression was used to assess if the output elevation data of the probes are correct and follow a linear relationship with voltage. Figure 3 shows the average values of voltage for each elevation. With a representative linear equation for the elevation to voltage relationship, we now apply the by proposed methodology of the ITTC Procedure “Uncertainty analysis Instrument Calibration” in which a number of methods to assess uncertainties in regression analysis are proposed   Figure 3: Linear regression on WP1 3.2. Uncertainty in noisy signal The document “Measurements and their Uncertainties” from T.P.A. Hase and I.G Hughes shows how to determine uncertainty from a noisy signal as a function of time. The proposed method was implemented for the voltage signal of the wave probes and also the elevation measurements. This method consists on taking all the points in a range where the signal appears constant and calculating the ‘time averaged mean’ and standard deviation. The standard error (or uncertainty) is then the result of the standard deviation divided by the square root of the number of the sample: 𝛼 =𝜎𝑁−1√𝑁 (1) where 𝛼 is the standard error (uncertainty), 𝜎𝑁−1 the standard deviation, 𝑁 the number of samples. The results are best displayed as a histogram shown in Figure 4. 4. RESULTS 4.1. Linear regression analysis All mean values determined are summarise in the following table, these values allow calculation of the correlation between elevation and voltage and the assessment of the quality of the correlation with the 𝑅2 value.  To compare the six wave probes, the correlations are plotted in Figure 5 where we can see that better agreement between probed for positive elevations. Returning to the ITTC procedure “Uncertainty Analysis Instrument Calibration”, 13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  4 the next step in the methodology is quantify the uncertainty of a linear regression analysis and the transfer function to convert voltage to physical units. Whilst the ITTC procedures provide a number of linear regression analysis methods, it does not provide guidance on the interpretation of the results. 4.2. Comparison When the calibration of all six waves probes was complete, a series of new tests were conducted with the voltage to elevation scaling applied in the data acquisition system. This scaling is express the minimum voltage for the minimum elevation and the maximum voltage for the maximum elevation in order to provide a linear correlation.  A comparison was conducted to calculate the voltage from the elevation recorded with the intercept and slope from the min/max values input in LabVIEW. From this voltage we calculate a new elevation using the intercept and slope from the linear regression equations to examine the impact.  Figure 4: WP1 distribution for each elevation of the calibration  Table 3: Linear regression values [nd]\[mm] 0 -300 -200 -100 0 100 intercept slope WP1 0.039789 -6.60492 -4.40179 -2.20608 0.007769 2.250465 0.025428991 0.022134691 WP2 0.025131 -6.53408 -4.3663 -2.20065 0.005854 2.259846 0.028057251 0.02195708 WP3 -0.02371 -6.49617 -4.32167 -2.16778 -0.03197 2.058112 -0.0455235 0.021420068 WP4 -0.01881 -7.07807 -4.92648 -2.59034 -0.06645 2.49958 -0.02804703 0.024024576 WP5 -0.00672 -6.89152 -4.68926 -2.39104 -0.07823 2.200492 -0.07109544 0.022859431 WP6 -0.09405 -7.2485 -4.91679 -2.70838 -0.28365 2.290077 -0.17741258 0.023793651 avg of avg -0.01306 -6.80888 -4.60371 -2.37738 -0.07445 2.259762 -0.04476538 0.02269825  13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  5  Table 5: WPI results from ITTC procedure   Inv 2T student t @ 95% confident 2.570581836x values  [mm] 0 -300 -200 -100 0 100x average [mm] -83.33333333Sxx 150000y values [V] 0.039788576 -6.6049 -4.4018 -2.2061 0.00777 2.25046intercept [V] 0.025428991slope [V/mm] 0.022134691Residual 0.014359585 0.01006 -0.0003 -0.018 -0.0177 0.01157Res.^2 0.000206198 0.0001 8.1E-08 0.00033 0.00031 0.00013SSR 0.001078567SEE 0.016420769Standardized residual 0.874477016 0.61257 -0.0173 -1.0986 -1.0754 0.70438ub 4.23982E-05ua 0.006703751uncertainty for the curve fit (mm) +|- 2.831099965 +|- 3.13 +|- 2.88 +|- 2.78 +|- 2.83 +|- 3.03A -1.1488297B 45.17795064equation for conversion to physical unit A+B*VoltageInverse equation (Phys.Unit-A)/BA = -a/b B = 1/b+|- 2.913630731uncertainty in slopeuncertainty in interceptWave Probe 1Res = yi-a-bxiSum of the square of residualsStandard error estimation Table 4: Min/max value used in LabVIEW scaling  min max intercept slope x -300 100 intercept slope y WP1 -6.6 2.25 0.0375 0.022125 y WP2 -6.5 2.25 0.0625 0.021875 y WP3 -6.5 2.05 -0.0875 0.021375 y WP4 -7.078 2.49 0.098 0.02392 y WP5 -6.9 2.2 -0.075 0.02275 y WP6 -7.25 2.3 -0.0875 0.023875  Table 6a: Comparison analysis for elevation Record elevation[mm] Mean WP1 6.26 -296.84 107.24 6.33 Mean WP2 5.50 -295.55 108.12 4.71 Mean WP3 10.41 -292.28 111.15 9.75 Mean WP4 0.32 -295.52 113.34 0.81 Mean WP5 11.27 -294.13 112.45 10.93 Mean WP6 4.63 -293.20 111.11 3.20  Table 6c: Comparison analysis elevation estimates Estimation of Voltage (V) Mean WP1 0.176 -6.530 2.410 0.178 Mean WP2 0.183 -6.403 2.428 0.165 Mean WP3 0.135 -6.335 2.288 0.121 Mean WP4 0.106 -6.971 2.809 0.117 Mean WP5 0.181 -6.766 2.483 0.174 Mean WP6 0.023 -7.088 2.565 -0.011  Table 6d: Comparison analysis elevation difference  Elevation Difference [mm] Mean WP1 -0.543 -0.675 -0.498 -0.543 -0.565 WP2 -1.548 -2.673 -1.164 -1.551 -1.734 WP3 1.982 1.345 2.194 1.980 1.875 WP4 -5.245 -6.533 -4.753 -5.243 -5.444 WP5 0.225 -1.237 0.709 0.223 -0.020 WP6 -3.795 -2.776 -4.159 -3.790 -3.630  Table 6b: Comparison analysis voltage estimates Estimation of Voltage (V) Mean WP1 0.176 -6.530 2.410 0.178 Mean WP2 0.183 -6.403 2.428 0.165 Mean WP3 0.135 -6.335 2.288 0.121 Mean WP4 0.106 -6.971 2.809 0.117 Mean WP5 0.181 -6.766 2.483 0.174 Mean WP6 0.023 -7.088 2.565 -0.011  13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  6 This method doesn’t express a standard error but highlights the importance of taking a suitable fit to the voltage to elevation equation to minimise uncertainty in data acquisition. According to the method in Measurements and their Uncertainties quoted earlier in this report. For each probe we can evaluate the standard error from the noisy signal when it’s at a constant elevation level. This work was conducted for the voltage signal and also the elevation signal. For the calculation we took the same ranges used to determine the mean values. The table with the different uncertainties are given below.  5. DISCUSSION AND FURTHER WORK The results from the linear regression are well correlated with the mean values of each signal. In future tests it could be beneficial to increase the averaging period at each wave probe elevation to allow the impact of oscillations on the water surface to reduce. The calculations outlined in the ITTC procedure require further development into standardised methodologies to allow interpretation of the associated uncertainty. 6. CONCLUSION The linear regression analysis show that the wave probes have a correlation coefficient equal at more than 0.99. The noisy signal give standard error around +/- 0.2 mV but if we do the same calculation on the noisy signal in millimetres we got a standard error around +/-0.015 mm which doesn’t represent the +/- 0.2 mV. More work is required on the record signal in millimetres to identify the relation between the two uncertainties. 7. REFERENCES ASME, 2013. “Test Uncertainty, Performance Test Codes”. ASME PTC, 19.1 C. Wright, C. Desmond, and K. Lynch, “D2.20 Report on physical modelling methods for floating wind turbines,” MARINET project deliverable, 2015. Dao, M.H., Chew, L.W. and Zhang, Y., 2018. Modelling physical wave tank with flap paddle and porous beach in OpenFOAM. Ocean Engineering, 154, pp.204-215. Davidson, J., Giorgi, S. and Ringwood, J.V., 2015. Linear parametric hydrodynamic models for ocean wave energy converters identified from numerical wave tank experiments. Ocean Engineering, 103, pp.31-39. Desmond, C.J.; Hinrichs, J.-C.; Murphy, J. Uncertainty in the Physical Testing of Floating Wind Energy Platforms: Accuracy versus Precision. Energies 2019, 12, 435 Giorgi, S., Davidson, J. and Ringwood, J.V., 2016. Identification of wave energy device models from numerical wave tank data—Part 2: Data-based model determination. IEEE Transactions on Sustainable Energy, 7(3), pp.1020-1027 ITTC, 2014. “Guide to the Expression of Uncertainty in Experimental Hydrodynamics”. Rev. 02. ITTC, 2014. “Model tests for Offshore Wind Turbines”, Rev. 00. Jaksic V, O’Shea R, Cahill P, Murphy J, Mandic DP and Pakrashi V. (2015). Dynamic Response Signatures of a Scaled Model Platform for Floating Wind Turbines in an Ocean Wave Basin. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 373 (2035):20140078:1-20140078:18 Jaksic V, Wright CS, Murphy J, Afeef C, Ali SF, Mandic DP and Pakrashi V. (2015). Dynamic Response Mitigation of Floating Wind Turbine Platforms using Tuned Liquid Column Dampers. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 373 (2035):20140079:1-20140079:9 K. Muller, F. Sandner, H. Bredmose, J. Azcona, A. Manjock, R. Pereira, 2014. “Improved tank test procedure for scaled floating offshore wind turbines”. Proceedings of International Wind Engineering Conference 2014. O’Donnell D, Srbinovsky B, Murphy J, Popovici E and Pakrashi V. (2015). Sensor Measurement Figure 5: All wave probes signal from the calibration 13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  7 Strategies for Monitoring Offshore Wind and Wave Energy Devices. Institute of Physics, Journal of Physics, Conference Series, 628(1), 012117-1-8. O’Donnell D, Murphy J, Desmond C, Jaksic V and Pakrashi V. (2017). Tuned Liquid Column Damper based Reduction of Dynamic Responses of Scaled Offshore Platforms in Different Ocean Wave Basins. Journal of Physics, Conference Series, 842, 012043. Pakrashi V, O’Shea R, Jaksic V and Murphy J. (2015). The Hurst Exponent as an Indicator of the Behaviour of a Model Monopile in an Ocean Wave Testing Basin. Institute of Physics, Journal of Physics, Conference Series, 628(1), 012057-1-8. R. James and M. Ros. “Floating Offshore   Wind: Market and Technology Review”. Carbon Trust, June 2015.. S. Steen, 2014. “Experimental Methods in Marine Hydrodynamics”. Lecture Notes, Marine Technology Centre, Trondheim, Norway.  Wright C, O’Sullivan K, Murphy J and Pakrashi V. (2015). Experimental Comparison of Dynamic Responses of a Tension Moored Floating Wind Turbine Platform with and without Spring Dampers. Institute of Physics, Journal of Physics, Conference Series, 628(1), 012056-1-8.  

English

The assessment of water surface elevation uncertainty in a hydraulics laboratory

SNU Open Repository and Archive

13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  1 The Assessment of Water Surface Elevation Uncertainty in a Hydraulics Laboratory   Cian Desmond MaREI Centre, University College Cork, Cork, Ireland. Benoit Buret MaREI Centre, University College Cork, Cork, Ireland. Matthew Shanley MaREI Centre, University College Cork, Cork, Ireland. Jimmy Murphy MaREI Centre, University College Cork, Cork, Ireland. Vikram Pakrashi Dynamical Systems and Risk Laboratory, School of Mechanical and Materials Engineering, University College Dublin, Ireland; and MaREI Centre, University College Dublin, Dublin, Ireland. ABSTRACT: Physical model testing forms a critical part of the development process for offshore renewable energy (ORE) technologies.  Devices and structures generally follow a Technology Readiness Level (TRL) development pathway which has nine steps ranging from the initial idea (TRL1) to commercialisation (TRL9). In ORE, technologies are tested extensively in laboratory environments up to TRL4 after which a decision is made as to whether a particular technology has sufficient potential to justify moving to open sea environments where the costs can be much higher. Therefore, physical model testing plays a critical role in the development process and in recent years increased emphasis has been placed on improving quality procedures and implementing best practice methodologies. The International Towing Tank Conference (ITTC) and the International Electrotechnical Commission (IEC) have been developing testing standards whilst European Union funded projects such as Equimar, MaRINET and MaRINET2 have been working with testing infrastructures in developing a more uniform approach to testing. However, a standardised approach to the assessment of uncertainty in physical testing has yet to emerge. This paper focuses on and estimates the variation associated with wave elevation measurements using conductive wave probes in a hydraulics laboratory, a key input in all physical testing analysis.  1. INTRODUCTION With the installation of the 30MW Hywind pilot project in 2017 and the ongoing works on the 50MW Kincardine farm, Scotland, Floating Offshore Wind Turbines (FOWT) are now a commercial reality. However, many floating wind platform concepts are still progressing through the Technology Readiness Levels (TRLs) via a combination of experimental and physical testing, over 30 such concepts have been identified [1]. The progression of these technologies through the TRLs has resulted in wealth of fundamental research in the area of floating wind energy to support the advancement to commercialisation. The systematic assessment of experimental uncertainty   has only emerged in the past 15 years [2]. Guidelines are provided for the assessment of uncertainty in tank testing by both ASME [3] and the ITTC [4] with specific guidance provided by 13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  2 the ITTC [5] for the testing of offshore wind turbines. However, these do not provide a systemic approach to the assessment of experimental uncertainty or variation. There have been several recent studies on developing output-only markers for monitoring scaled renewable energy device platforms [8-10], assessing control efficiency [11-13] and even understanding the variations of responses of such scaled structures for various sensors [14]. While these results are important in terms of establishing an experimental benchmark, their results are also fundamentally dependent on the variation and uncertainty of the wave heights generated in the basin. There have been some limited and excellent work around addressing this uncertainty and error [15-17], but there is still a need to experimentally expand this topic further due to the overall paucity of literature in this topic. This paper takes this need of contributing to the experimental evidence base of such variation from wave basin tests and focuses on the assessment of uncertainty in the measurement of wave elevation using conductive wave probes during physical test campaigns. Accurate wave elevation data is vital for all analysis emanating from physical testing. The data used in this report are from an experimental campaign conducted in the Lir National Ocean Test Facility, in the ERI MaREI Centre, University College Cork. A total of six conductive waves probes were used to measure the water elevation. For each probe, a linear regression analysis has been investigated, as well as the uncertainty of the wave probe signal. The results are expected to be helpful for establishing better the Technological Readiness Levels (TRLs) of the various Offshore Renewable Energy (ORE) device concepts. 2. TEST CONDITIONS 2.1. Deep ocean basin specifications The basin shown in Figure 1 below has dimension of 35 m long, 12 m wide and 3 m deep. The basin is equipped with 16 hinged force feedback paddle capable of a peak wave generation condition of the significant wave height Hs =0.6m, peak period Tp =2.7s and the maximum wave height Hmax =1.1m. The water depth can be adjusted thanks to movable floor until the maximum of 3m deep. During the wave probe calibration, the paddles were stationary and the water depth was set at 750 mm to access to adjust the wave probe elevation.   Figure 1: Schematic view of the Lir National Ocean Test Facility: Deep Ocean Basin 2.2. Wave probe specifications The wave probes are resistance probes which output voltage which is directly related to the water surface elevation. During calibration the wave probes were spaced as per Table 1, the first wave probe (WP1) was closest to the paddles and the sixth (WP6) is the one nearest to the beach.   Table 1: Wave probe spacing for experiments. Wave Probe WP1 WP2 WP3 WP4 WP5 WP6 Distance to the WP1 (m) 0.00 0.15 0.28 0.57 1.16 2.44 2.3. Calibration The calibration methodology for the wave probes consists of raising and lowering in still water at set elevations and recording the output voltage for each elevation. The elevations listed in Table 2 were used. For each wave probe, the voltage at each elevation were recorded. Having recorded these data, the linearity of the elevation to voltage relationships were assessed.      13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  3 Table 2. Recorded elevations during a wave probe calibration. Elevation recorded (mm) 0  -300 -200  -100 0 100 3. ANALYSIS METHODS Figure 2 shows a typical signal recorded during a wave probe calibration. To determine the average value at a constant elevation, ranges were determined to calculate the mean voltage signal at each elevation. In order to avoid errors, a period when the disturbances to the water surface elevation caused by the adjustment of the wave probes were selected. A minimum of 90 second was required to calculate the mean of the signal.   Figure 2: WP1 calibration signal 3.1. Linear regression analysis With all mean values for each elevation for each probes, a linear regression was used to assess if the output elevation data of the probes are correct and follow a linear relationship with voltage. Figure 3 shows the average values of voltage for each elevation. With a representative linear equation for the elevation to voltage relationship, we now apply the by proposed methodology of the ITTC Procedure “Uncertainty analysis Instrument Calibration” in which a number of methods to assess uncertainties in regression analysis are proposed   Figure 3: Linear regression on WP1 3.2. Uncertainty in noisy signal The document “Measurements and their Uncertainties” from T.P.A. Hase and I.G Hughes shows how to determine uncertainty from a noisy signal as a function of time. The proposed method was implemented for the voltage signal of the wave probes and also the elevation measurements. This method consists on taking all the points in a range where the signal appears constant and calculating the ‘time averaged mean’ and standard deviation. The standard error (or uncertainty) is then the result of the standard deviation divided by the square root of the number of the sample: 𝛼 =𝜎𝑁−1√𝑁 (1) where 𝛼 is the standard error (uncertainty), 𝜎𝑁−1 the standard deviation, 𝑁 the number of samples. The results are best displayed as a histogram shown in Figure 4. 4. RESULTS 4.1. Linear regression analysis All mean values determined are summarise in the following table, these values allow calculation of the correlation between elevation and voltage and the assessment of the quality of the correlation with the 𝑅2 value.  To compare the six wave probes, the correlations are plotted in Figure 5 where we can see that better agreement between probed for positive elevations. Returning to the ITTC procedure “Uncertainty Analysis Instrument Calibration”, 13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  4 the next step in the methodology is quantify the uncertainty of a linear regression analysis and the transfer function to convert voltage to physical units. Whilst the ITTC procedures provide a number of linear regression analysis methods, it does not provide guidance on the interpretation of the results. 4.2. Comparison When the calibration of all six waves probes was complete, a series of new tests were conducted with the voltage to elevation scaling applied in the data acquisition system. This scaling is express the minimum voltage for the minimum elevation and the maximum voltage for the maximum elevation in order to provide a linear correlation.  A comparison was conducted to calculate the voltage from the elevation recorded with the intercept and slope from the min/max values input in LabVIEW. From this voltage we calculate a new elevation using the intercept and slope from the linear regression equations to examine the impact.  Figure 4: WP1 distribution for each elevation of the calibration  Table 3: Linear regression values [nd]\[mm] 0 -300 -200 -100 0 100 intercept slope WP1 0.039789 -6.60492 -4.40179 -2.20608 0.007769 2.250465 0.025428991 0.022134691 WP2 0.025131 -6.53408 -4.3663 -2.20065 0.005854 2.259846 0.028057251 0.02195708 WP3 -0.02371 -6.49617 -4.32167 -2.16778 -0.03197 2.058112 -0.0455235 0.021420068 WP4 -0.01881 -7.07807 -4.92648 -2.59034 -0.06645 2.49958 -0.02804703 0.024024576 WP5 -0.00672 -6.89152 -4.68926 -2.39104 -0.07823 2.200492 -0.07109544 0.022859431 WP6 -0.09405 -7.2485 -4.91679 -2.70838 -0.28365 2.290077 -0.17741258 0.023793651 avg of avg -0.01306 -6.80888 -4.60371 -2.37738 -0.07445 2.259762 -0.04476538 0.02269825  13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  5  Table 5: WPI results from ITTC procedure   Inv 2T student t @ 95% confident 2.570581836x values  [mm] 0 -300 -200 -100 0 100x average [mm] -83.33333333Sxx 150000y values [V] 0.039788576 -6.6049 -4.4018 -2.2061 0.00777 2.25046intercept [V] 0.025428991slope [V/mm] 0.022134691Residual 0.014359585 0.01006 -0.0003 -0.018 -0.0177 0.01157Res.^2 0.000206198 0.0001 8.1E-08 0.00033 0.00031 0.00013SSR 0.001078567SEE 0.016420769Standardized residual 0.874477016 0.61257 -0.0173 -1.0986 -1.0754 0.70438ub 4.23982E-05ua 0.006703751uncertainty for the curve fit (mm) +|- 2.831099965 +|- 3.13 +|- 2.88 +|- 2.78 +|- 2.83 +|- 3.03A -1.1488297B 45.17795064equation for conversion to physical unit A+B*VoltageInverse equation (Phys.Unit-A)/BA = -a/b B = 1/b+|- 2.913630731uncertainty in slopeuncertainty in interceptWave Probe 1Res = yi-a-bxiSum of the square of residualsStandard error estimation Table 4: Min/max value used in LabVIEW scaling  min max intercept slope x -300 100 intercept slope y WP1 -6.6 2.25 0.0375 0.022125 y WP2 -6.5 2.25 0.0625 0.021875 y WP3 -6.5 2.05 -0.0875 0.021375 y WP4 -7.078 2.49 0.098 0.02392 y WP5 -6.9 2.2 -0.075 0.02275 y WP6 -7.25 2.3 -0.0875 0.023875  Table 6a: Comparison analysis for elevation Record elevation[mm] Mean WP1 6.26 -296.84 107.24 6.33 Mean WP2 5.50 -295.55 108.12 4.71 Mean WP3 10.41 -292.28 111.15 9.75 Mean WP4 0.32 -295.52 113.34 0.81 Mean WP5 11.27 -294.13 112.45 10.93 Mean WP6 4.63 -293.20 111.11 3.20  Table 6c: Comparison analysis elevation estimates Estimation of Voltage (V) Mean WP1 0.176 -6.530 2.410 0.178 Mean WP2 0.183 -6.403 2.428 0.165 Mean WP3 0.135 -6.335 2.288 0.121 Mean WP4 0.106 -6.971 2.809 0.117 Mean WP5 0.181 -6.766 2.483 0.174 Mean WP6 0.023 -7.088 2.565 -0.011  Table 6d: Comparison analysis elevation difference  Elevation Difference [mm] Mean WP1 -0.543 -0.675 -0.498 -0.543 -0.565 WP2 -1.548 -2.673 -1.164 -1.551 -1.734 WP3 1.982 1.345 2.194 1.980 1.875 WP4 -5.245 -6.533 -4.753 -5.243 -5.444 WP5 0.225 -1.237 0.709 0.223 -0.020 WP6 -3.795 -2.776 -4.159 -3.790 -3.630  Table 6b: Comparison analysis voltage estimates Estimation of Voltage (V) Mean WP1 0.176 -6.530 2.410 0.178 Mean WP2 0.183 -6.403 2.428 0.165 Mean WP3 0.135 -6.335 2.288 0.121 Mean WP4 0.106 -6.971 2.809 0.117 Mean WP5 0.181 -6.766 2.483 0.174 Mean WP6 0.023 -7.088 2.565 -0.011  13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  6 This method doesn’t express a standard error but highlights the importance of taking a suitable fit to the voltage to elevation equation to minimise uncertainty in data acquisition. According to the method in Measurements and their Uncertainties quoted earlier in this report. For each probe we can evaluate the standard error from the noisy signal when it’s at a constant elevation level. This work was conducted for the voltage signal and also the elevation signal. For the calculation we took the same ranges used to determine the mean values. The table with the different uncertainties are given below.  5. DISCUSSION AND FURTHER WORK The results from the linear regression are well correlated with the mean values of each signal. In future tests it could be beneficial to increase the averaging period at each wave probe elevation to allow the impact of oscillations on the water surface to reduce. The calculations outlined in the ITTC procedure require further development into standardised methodologies to allow interpretation of the associated uncertainty. 6. CONCLUSION The linear regression analysis show that the wave probes have a correlation coefficient equal at more than 0.99. The noisy signal give standard error around +/- 0.2 mV but if we do the same calculation on the noisy signal in millimetres we got a standard error around +/-0.015 mm which doesn’t represent the +/- 0.2 mV. More work is required on the record signal in millimetres to identify the relation between the two uncertainties. 7. REFERENCES ASME, 2013. “Test Uncertainty, Performance Test Codes”. ASME PTC, 19.1 C. Wright, C. Desmond, and K. Lynch, “D2.20 Report on physical modelling methods for floating wind turbines,” MARINET project deliverable, 2015. Dao, M.H., Chew, L.W. and Zhang, Y., 2018. Modelling physical wave tank with flap paddle and porous beach in OpenFOAM. Ocean Engineering, 154, pp.204-215. Davidson, J., Giorgi, S. and Ringwood, J.V., 2015. Linear parametric hydrodynamic models for ocean wave energy converters identified from numerical wave tank experiments. Ocean Engineering, 103, pp.31-39. Desmond, C.J.; Hinrichs, J.-C.; Murphy, J. Uncertainty in the Physical Testing of Floating Wind Energy Platforms: Accuracy versus Precision. Energies 2019, 12, 435 Giorgi, S., Davidson, J. and Ringwood, J.V., 2016. Identification of wave energy device models from numerical wave tank data—Part 2: Data-based model determination. IEEE Transactions on Sustainable Energy, 7(3), pp.1020-1027 ITTC, 2014. “Guide to the Expression of Uncertainty in Experimental Hydrodynamics”. Rev. 02. ITTC, 2014. “Model tests for Offshore Wind Turbines”, Rev. 00. Jaksic V, O’Shea R, Cahill P, Murphy J, Mandic DP and Pakrashi V. (2015). Dynamic Response Signatures of a Scaled Model Platform for Floating Wind Turbines in an Ocean Wave Basin. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 373 (2035):20140078:1-20140078:18 Jaksic V, Wright CS, Murphy J, Afeef C, Ali SF, Mandic DP and Pakrashi V. (2015). Dynamic Response Mitigation of Floating Wind Turbine Platforms using Tuned Liquid Column Dampers. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 373 (2035):20140079:1-20140079:9 K. Muller, F. Sandner, H. Bredmose, J. Azcona, A. Manjock, R. Pereira, 2014. “Improved tank test procedure for scaled floating offshore wind turbines”. Proceedings of International Wind Engineering Conference 2014. O’Donnell D, Srbinovsky B, Murphy J, Popovici E and Pakrashi V. (2015). Sensor Measurement Figure 5: All wave probes signal from the calibration 13th International Conference on Applications of Statistics and Probability in Civil Engineering, ICASP13 Seoul, South Korea, May 26-30, 2019  7 Strategies for Monitoring Offshore Wind and Wave Energy Devices. Institute of Physics, Journal of Physics, Conference Series, 628(1), 012117-1-8. O’Donnell D, Murphy J, Desmond C, Jaksic V and Pakrashi V. (2017). Tuned Liquid Column Damper based Reduction of Dynamic Responses of Scaled Offshore Platforms in Different Ocean Wave Basins. Journal of Physics, Conference Series, 842, 012043. Pakrashi V, O’Shea R, Jaksic V and Murphy J. (2015). The Hurst Exponent as an Indicator of the Behaviour of a Model Monopile in an Ocean Wave Testing Basin. Institute of Physics, Journal of Physics, Conference Series, 628(1), 012057-1-8. R. James and M. Ros. “Floating Offshore   Wind: Market and Technology Review”. Carbon Trust, June 2015.. S. Steen, 2014. “Experimental Methods in Marine Hydrodynamics”. Lecture Notes, Marine Technology Centre, Trondheim, Norway.  Wright C, O’Sullivan K, Murphy J and Pakrashi V. (2015). Experimental Comparison of Dynamic Responses of a Tension Moored Floating Wind Turbine Platform with and without Spring Dampers. Institute of Physics, Journal of Physics, Conference Series, 628(1), 012056-1-8.  

The Assessment of Water Surface Elevation Uncertainty in a Hydraulics Laboratory

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The Assessment of Water Surface Elevation Uncertainty in a Hydraulics Laboratory

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