Estimating the Spatial Sensitivity Function of A Light Sensor N. K

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Presentation transcript:

Estimating the Spatial Sensitivity Function of A Light Sensor N. K Estimating the Spatial Sensitivity Function of A Light Sensor N. K. Malakar, A. J. Mesiti and K. H. Knuth University at Albany, State University of New York, Albany, NY Introduction SSF: Observations and Predictions Results This project focuses on estimating the Spatial Sensitivity Function (SSF) of a simple light intensity sensor. This light sensor has been used in the Knuth Cyberphysics Laboratory on a robotic arm that performs its own experiments to locate a white circle in a dark field (Knuth et al., 2007). We model the light sensor’s response to a hypothetical stimulus by Mixture of Gaussians (MOG) to make predictions about the data. We apply Bayesian inference to learn about the underlying components of MOG model and compare the evidence on the light of observation data. The light sensor was swept across a black background followed by a white background. We rotated the sensor to get four sets of intensity data. Nested Sampling was used to infer the SSF. Mixtures of Gaussians were tested with different number of objects in a Nested Sampling algorithm. The evidence was computed for each model. Sensor Orientations Model: MOG Evidence (250 Objects) Evidence (200 Objects) Evidence (100 Objects) Number of Parameters Asymmetric 1G -440.3561 -440.0029 -440.0399 4 Symmetric 1G - -477.7277 3 Asymmetric 2G -433.7316 -434.2040 -434.5098 10 Symmetric 3G -436.6882 12 Asymmetric 3G -436.1786 -436.1131 -435.9219 15 Asymmetric 4G -436.5303 -435.9072 -436.1423 20 Symmetric 4G -441.2039 16 Asymmetric 5G -438.8655 -439.5407 -440.6841 25 The LEGO NXT sensor Asymmetric Gaussian: SSF and its predictions Methods Orientation#1 A Mixture of Gaussians (MOG) is used to model the SSF. Asymmetric 2 MOG: SSF and its predictions Orientation#2 where denotes the parameters of the Gaussian. Intensity Function: Future Work where x is the position of the sensor and bx is the position of the boundary. Only one height has been considered at this time, future works will involve motion of the sensor in three dimensional space and computing SSF for each height A Non-Parametric Grid model will also be considered for the SSF. The SSF may be better characterized using more complex black and white patterns. Orientation#3 Asymmetric 3 MOG: SSF and its predictions The sensor output is a convolution of the MOG model with the background intensity function: Orientation#4 With student-t as the likelihood and a flat prior, the log Posterior for four sets of observations is : Asymmetric 4 MOG: SSF and its predictions Acknowledgements We used Nested Sampling (Skilling 2005) to infer the parameter values. The work was supported partially by a University at Albany Benevolent Research Grant (Malakar) and a Faculty Research Award Program Grant (Knuth). Asymmetric 5 MOG: SSF and its predictions