The Regular Interaction Pattern among Odorants of the Same Type and Its Application in Odor Intensity Assessment

Yan, Luchun; Liu, Jiemin; Jiang, Shen; Wu, Chuandong; Gao, Kewei

doi:10.3390/s17071624

Cited by 42 publications

(25 citation statements)

References 36 publications

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“…As typical odor pollutants in odor sources like landfills and sewage treatment plants, odor data (i.e., odor threshold, Table 1; olfactory measured odor intensity and chemical concentration) of ethyl acetate (EA), butyl acetate (BA), ethyl butyrate (EB), propionaldehyde (PA), n-valeraldehyde (VA), n-heptaldehyde (HEP), benzene (B), toluene (T), ethylbenzene (E), and some of their binary mixtures were collected from our previous studies [23][24][25]. In these experiments, the odor samples were prepared through transferring a certain amount of standard gas to an odor-free plastic bag (3 L volume; Sinodour, Tianjin, China) and diluted with purified air.…”

Section: Stimuli and Odor Datamentioning

confidence: 99%

“…Although many studies have established empirical models to explain the odor interaction phenomenon and made conclusions, we still hope to develop more analytical methods through the reasonable use of machine learning methods. Since it has been proved that there is a simple linear relationship between OI and lnOAV of an individual substance, we think that using the lnOAV value to represent the content of a component is also helpful in odor interaction studies [23,24]. As illustrated in Figure 2a, c, and d, scatter plots of the relationship between each component's content (in the form of lnOAV) and the odor interaction degree (in the form of OI reduction values; i.e., the color of each dot) was plotted.…”

Section: Svr-assisted Visual Analysis Of Odor Interactionmentioning

confidence: 99%

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Visual Analysis of Odor Interaction Based on Support Vector Regression Method

Yan

Liu

2020

Sensors

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The complex odor interaction between odorants makes it difficult to predict the odor intensity of their mixtures. The analysis method is currently one of the factors limiting our understanding of the odor interaction laws. We used a support vector regression algorithm to establish odor intensity prediction models for binary esters, aldehydes, and aromatic hydrocarbon mixtures, respectively. The prediction accuracy to both training samples and test samples demonstrated the high prediction capacity of the support vector regression model. Then the optimized model was used to generate extra odor data by predicting the odor intensity of more simulated samples with various mixing ratios and concentration levels. Based on these olfactory measured and model predicted data, the odor interaction was analyzed in the form of contour maps. This intuitive method showed more details about the odor interaction pattern in the binary mixture. We found that that the antagonism effect was commonly observed in these binary mixtures and the interaction degree was more intense when the components' mixing ratio was close. Meanwhile, the odor intensity level of the odor mixture barely influenced the interaction degree. The machine learning algorithms were considered promising tools in odor researches.3 of 12 standard in odor intensity evaluation [26]. More details about the testing procedure and environmental requirements were described in these references. In this study, the collected dataset contains 31 samples of binary mixture EA+BA, 21 samples of EA+EB, 22 samples of BA+EB, 24 samples of PA+VA, 24 samples of PA+HEP, 24 samples of VA+HEP, 34 samples of B+T, 31 samples of B+E, and 24 samples of T+E.

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Section: Stimuli and Odor Datamentioning

confidence: 99%

Section: Svr-assisted Visual Analysis Of Odor Interactionmentioning

confidence: 99%

Visual Analysis of Odor Interaction Based on Support Vector Regression Method

Yan

Liu

2020

Sensors

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“…The coefficient α found in the equations (3) and (4) is approximately constant for one pair of mixture components. Recently, studies on the determination of this coefficient for compounds from the group of aldehydes, esters or aromatic hydrocarbons were carried out by researchers who determined its value at the level of: 0.1, 0.2 and 0.3 respectively [13].…”

Section: Odour Intensitymentioning

confidence: 99%

Electronic nose – an instrument for odour nuisances monitoring

Szulczyński

Gębicki

2019

E3S Web Conf.

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An increasingly frequent problem of people living in urban agglomerations is the occurrence of odour nuisance. Although the source of these nuisances is different, their common feature is that they are a complex mixture of odour compounds with different odour thresholds. However, from a practical point of view, the most valuable would be a direct link between the odour intensity and the results of on-line analytical air monitoring. Such a possibility is created by the use of electronic noses (devices that are supposed to imitate the human sense of smell) to measure odours. The paper presents the use of an electronic nose combined with multiple liear regression model (MLR) to determine the odour intensity of the two-component mixture samples of commonly known odour compounds: trimethylamine (TMA) and triethylamine (TEA) in concentration range 50–200 ppm v/v. The obtained results were compared with the theoretical values determined using Zwaardemaker and euclidean additivity (EA) models. For high concentrations of substances in the mixtures (> 150 ppm v/v), the masking effect was observed.

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“…In the last years, scientists have focused on developing devices analogue to human senses, such as electronic noses that once calibrated they can be used to perform odour assessment on a continuous basis at a minimum cost (Hudon, Guy, and Hermia 2000;Szulczynski et al 2018). However, the range of odour mixtures, concentrations and intensities that the device can detect is still limited (Yan et al 2017). Due to this limitation the use of these devices is still restricted at the moment to monitor environmental odours (Yan et al 2017).…”

Section: Introductionmentioning

confidence: 99%

“…However, the range of odour mixtures, concentrations and intensities that the device can detect is still limited (Yan et al 2017). Due to this limitation the use of these devices is still restricted at the moment to monitor environmental odours (Yan et al 2017). Scientists recommend to combine odour measurement procedures using the human nose as detector together with a scientific method and instruments (Brattoli et al 2011;Walker 2001).…”

Section: Introductionmentioning

confidence: 99%

Appraisal and identification of different sources of smell by primary school children in the air quality test chamber of the SenseLab

Moya

Bluyssen

2019

Intelligent Buildings International

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Previous studies have shown that next to 'human smell', 'stuffy air' is one of the discomforts that children report in classrooms. Besides, people's olfactory system is able to recognize the perceived odour intensity of various materials relatively well and in many cases the nose seems to be a better perceiver of pollutants than some equipment. In the underlying study, the aim was to expose 335 primary children to different sources of smell, and ask them to evaluate and identify those sources at individual level with their noses. Additionally, the possible effect of plants on the reduction and/or production of smells was tested. Selected sources of odour were placed in different containers and the children were asked how they feel about the smell and to identify their source. The results showed statistically significant differences among children's evaluations of different smells, a link between preference and recognition of odours, and, no statistical difference in the assessment of the smells when the potted plants were placed inside the CLIMPAQ. The results confirm the need to include sensory assessments in the evaluation of IAQ together with physical evaluations. Future studies on the effect of using active vegetation systems instead of passive systems are recommended.

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The Regular Interaction Pattern among Odorants of the Same Type and Its Application in Odor Intensity Assessment

Cited by 42 publications

References 36 publications

Visual Analysis of Odor Interaction Based on Support Vector Regression Method

Visual Analysis of Odor Interaction Based on Support Vector Regression Method

Electronic nose – an instrument for odour nuisances monitoring

Appraisal and identification of different sources of smell by primary school children in the air quality test chamber of the SenseLab

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