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Contaminant-detection-in-packaged-cocoa-hazelnut-spread-jars-using-Microwaves-Sensing-and-Machine-Learning-9.0GHz(Urbinati)

Contaminant-detection-in-packaged-cocoa-hazelnut-spread-jars-using-Microwaves-Sensing-and-Machine-Learning-9.0GHz(Urbinati)

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Contaminant-detection-in-packaged-cocoa-hazelnut-spread-jars-using-Microwaves-Sensing-and-Machine-Learning-9.0GHz(Urbinati) ---------------- This dataset is part of a series of five different datasets each one measured with a different microwave frequency: 9.0, 9.5, 10.0, 10.5, 11.0 GHz. PAY ATTENTION: THE DATASET PRESENTED IN THIS PAGE HAS BEEN ACQUIRED AT 9.0 GHz! IF YOU ARE LOOKING FOR THE OTHER FOUR DATASETS, VISIT THE OPENML PROFILE OF THE AUTHOR OF THIS DATASET. The following description is valid for all the five datasets. Dataset description. To detect contaminants accidentally included in industrial food, Microwave Sensing (MWS) can be used as a contactless detection method, in particular when the food is already packaged. MWS uses microwaves to illuminate the target object through a set of antennas, records the scattered waves, and uses Machine Learning to predict the presence of contaminants inside the target object. In this application the target object is a cocoa-hazelnut spread jar and each instance (sample) of this dataset consists in 30 scattering parameters of the network composed by: antennas, target object (a jar w/ or w/o a contaminant inside) and medium (i.e. the air) in between. The types of contaminants vary from metal to glass and plastic. Each sample has been measured at five different microwave frequencies that are: 9.0, 9.5, 10.0, 10.5, 11.0 GHz. PAY ATTENTION: THE DATASET PRESENTED IN THIS PAGE HAS BEEN ACQUIRED AT 9.0 GHz! IF YOU ARE LOOKING FOR THE OTHER FOUR DATASETS, VISIT THE OPENML PROFILE OF THE AUTHOR OF THIS DATASET. Data Set Characteristics: :Microwave frequency used for acquisition: 9.0 GHz :Total Number of Instances: 2400 :Total Number of Uncontaminated Instances: 1200 :Total Number of Contaminated Instances: 1200 :Total Number of Classes: 11 :Target: The last column, column 31, contains the class label as integer value :Number of Contaminated Instances Divided Per Class (full explanation and pictures in [2]): - "air_surface" (i.e. cap-shape plastic with the same dielectric constant of the air): 200 - "big_pink_plastic_shere_middle": 100 - "big_pink_plastic_shere_surface": 100 - "glass_fragment_middle": 100 - "glass_fragment_surface": 100 - "small_metal_sphere_middle": 100 - "small_metal_sphere_surface": 100 - "small_plastic_sphere_middle": 100 - "small_plastic_sphere_surface": 100 - "small_triangular_plastic_fragment_surface": 200 "surface" means that the instance was placed on top of the cocoa-hazelnut spread, at the spread-air interface "middle" means that the instance was placed in the middle of the jar filled with cocoa-hazelnut spread :Number of Attributes in a generic Instance: 30 :Attribute Information: This is the 6x6 Scattering Matrix (S): S = [ s12, s13, s14, s15, s16, s21, s23, s24, s25, s26, s31, s32, s34, s35, s36, s41, s42, s43, s45, s46, s51, s52, s53, s54, s56, s61, s62, s63, s64, s65, ] The first 30 attributes (columns) of an instance are the 15 elements of the triangular upper part of S. Since each of these elements is a complex number with real and imaginary parts, each instance is a vector of 15x2=30 attributes. The real (real) and imaginary (img) parts of each element are placed one after the other. The scattering parameters are ordered row by row from left to right, e.g.: s12_real, s12_img, s13_real, s13_img, ..., s16_real, s16_img, s21_real, s21_img, ... . The self-scattering parameters, i.e. those placed on the main diagional of S, are not part of the dataset, as exaplined in [1]. Note: This dataset is realeased without pre-processing. For more information read the reference papers: [1] L. Urbinati, M. Ricci, G. Turvani, J. A. T. Vasquez, F. Vipiana and M. R. Casu, "A Machine-Learning Based Microwave Sensing Approach to Food Contaminant Detection," 2020 IEEE International Symposium on Circuits and Systems (ISCAS), Seville, Spain, 2020, pp. 1-5, doi: 10.1109/ISCAS45731.2020.9181293 Link to the paper: https://ieeexplore.ieee.org/abstract/document/9181293 [2] M. Ricci, B. Stitic, L. Urbinati, G. D. Guglielmo, J. A. T. Vasquez, L. P. Carloni, F. Vipiana, and M. R. Casu, "Machine-learning-based microwave sensing: A case study for the food industry," IEEE Journal on Emerging and Selected Topics in Circuits and Systems, vol. 11, no. 3, pp. 503-514, 2021 Link to the paper: https://ieeexplore.ieee.org/abstract/document/9489295

31 features

class (target)numeric2 unique values
0 missing
s12numeric1854 unique values
0 missing
s13numeric1865 unique values
0 missing
s14numeric1928 unique values
0 missing
s15numeric1875 unique values
0 missing
s16numeric1423 unique values
0 missing
s21numeric1710 unique values
0 missing
s23numeric1428 unique values
0 missing
s24numeric1436 unique values
0 missing
s25numeric1349 unique values
0 missing
s26numeric1422 unique values
0 missing
s31numeric1670 unique values
0 missing
s32numeric1507 unique values
0 missing
s34numeric1226 unique values
0 missing
s35numeric1261 unique values
0 missing
s36numeric1015 unique values
0 missing
s41numeric1041 unique values
0 missing
s42numeric1525 unique values
0 missing
s43numeric1450 unique values
0 missing
s45numeric611 unique values
0 missing
s46numeric932 unique values
0 missing
s51numeric957 unique values
0 missing
s52numeric931 unique values
0 missing
s53numeric1571 unique values
0 missing
s54numeric1557 unique values
0 missing
s56numeric797 unique values
0 missing
s61numeric690 unique values
0 missing
s62numeric1038 unique values
0 missing
s63numeric1062 unique values
0 missing
s64numeric924 unique values
0 missing
s65numeric1219 unique values
0 missing

19 properties

2400
Number of instances (rows) of the dataset.
31
Number of attributes (columns) of the dataset.
0
Number of distinct values of the target attribute (if it is nominal).
0
Number of missing values in the dataset.
0
Number of instances with at least one value missing.
31
Number of numeric attributes.
0
Number of nominal attributes.
0
Percentage of binary attributes.
0
Percentage of instances having missing values.
0
Percentage of missing values.
1
Average class difference between consecutive instances.
100
Percentage of numeric attributes.
0.01
Number of attributes divided by the number of instances.
0
Percentage of nominal attributes.
Percentage of instances belonging to the most frequent class.
Number of instances belonging to the most frequent class.
Percentage of instances belonging to the least frequent class.
Number of instances belonging to the least frequent class.
0
Number of binary attributes.

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