Next Article in Journal
Natural Frequency Response Evaluation for RC Beams Affected by Steel Corrosion Using Acceleration Sensors
Previous Article in Journal
Non-Invasive Estimation of Machining Parameters during End-Milling Operations Based on Acoustic Emission
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Exploratory Analysis of Urban Climate Using a Gap-Filled Landsat 8 Land Surface Temperature Data Set

by
Sorin Cheval
1,2,3,4,*,
Alexandru Dumitrescu
1,3,4 and
Vlad-Alexandru Amihaesei
1,5
1
Meteo Romania (National Meteorological Administration), 013686 Bucharest, Romania
2
Henri Coandă Air Force Academy, 500187 Brașov, Romania
3
Research Institute of the University of Bucharest, 050663 Bucharest, Romania
4
Romanian Association of Applied Meteorology and Education, 010041 Bucharest, Romania
5
GeoScience Doctoral School Department, “Alexandru Ioan Cuza” University, 700506 Iasi, Romania
*
Author to whom correspondence should be addressed.
Sensors 2020, 20(18), 5336; https://doi.org/10.3390/s20185336
Submission received: 6 August 2020 / Revised: 15 September 2020 / Accepted: 15 September 2020 / Published: 17 September 2020
(This article belongs to the Section Remote Sensors)

Abstract

:
The Landsat 8 satellites have retrieved land surface temperature (LST) resampled at a 30-m spatial resolution since 2013, but the urban climate studies frequently use a limited number of images due to the problems related to missing data over the city of interest. This paper endorses a procedure for building a long-term gap-free LST data set in an urban area using the high-resolution Landsat 8 imagery. The study is applied on 94 images available through 2013–2018 over Bucharest (Romania). The raw images containing between 1.1% and 58.4% missing LST data were filled in using the Data INterpolating Empirical Orthogonal Functions (DINEOF) algorithm implemented in the sinkr R packages. The resulting high-spatial-resolution gap-filled land surface temperature data set was used to explore the LST climatology over Bucharest (Romania) an urban area, at a monthly, seasonal, and annual scale. The performance of the gap-filling method was checked using a cross-validation procedure, and the results pledge for the development of an LST-based urban climatology.

1. Introduction

The increasing population and the permanent quest for comfort and safe shelter have triggered intense urbanization processes taking place all over the world, mainly in the 20th and 21st centuries. The built-up areas substantially modify the environment, and the features of the local atmospheric envelope are changed to the point that a new type of climate is formed. The urban climate is the resultant of a different composition of the radiation budget, higher temperature, and lower humidity values than the surrounding rural areas. The high heterogeneity of the urban environment is replicated in a corresponding diversity of the local climate conditions within a city. For example, green areas are cooler and more humid than impervious patches, urban canyons and squares disturb the wind flow, and building heights and density are so influential for the urban climate that they form the base of the definition of local climate zones (LCZs) [1,2,3]. As a consequence, urban climate modelling and weather forecasting require adequate data relevant for different urban microclimates.
Due to some insurmountable challenges related to the deployment of sensors, such as implementation and maintenance costs, it is very difficult to capture the climate of all distinct spatial tracks in a city using ground measurements. In recent years, urban meteorological networks (UMNs) have been implemented in several cities [4,5,6,7], and citizen observatories are increasingly used in urban climate research [8,9], but a full coverage of the climatic instances of a city is still problematic. Alternatively, the use of satellite remote sensing for retrieving the urban land surface temperature (LST) has been constantly intensified in the last decades, urged by easier access to low-cost ready-to-use products, larger spatial coverage, finer temporal resolutions, and an extended time span of availability. At present, the World Meteorological Organization (WMO) acknowledges 105 satellite instruments that have provided LST along time, categorized from primary to marginal relevance [10]. Several sensors that have provided LST products are particularly useful for the urban climate due to their suitable resolutions and time span (Table 1).
From a climatic perspective, the main differences between the satellite remote sensing products refer to the spatial-temporal resolutions and time span of available data. For urban climate studies, the ideal product will have ≤ a 1-km spatial resolution [11], daily frequency, and temporal continuity over the area of interest. In this respect, one can remark that the Landsat missions jointly operated by NASA and the U.S. Geological Survey have provided a series of Earth observation satellites since 1972. The spatial resolution of the Landsat series reached 30 m (resampled) and contributed significantly to the development of urban climate research [12,13,14]. The availability of such data has stimulated detailed investigations of the surface urban heat island (SUHI) and its correlation with the land use/land cover [15,16]. Nevertheless, the low frequency of full-coverage images, with all or the majority of pixels valid over certain areas, and the coarse temporal resolution (i.e., one image at 8 or 16 days) bias the potential benefits to use the Landsat series for urban climate research. Different solutions have been proposed to address such limitations or to improve the quality of the outputs. Cristóbal et al. (2009) [17] presented an enhanced methodology to retrieve LST from Landsat 4 TM, Landsat 5 TM, and Landsat 7 ETM+ using different water vapor ranges.
Sparse or even singular Landsat images were often used in urban climate studies [14,15], while temporally and spatially continuous data sets have been rarely employed simply because they are not available. For example, Lemus-Canovas et al. (2020) [18] estimated Barcelona’s metropolitan daytime hot and cold extremes using the LST retrieved from 24 Landsat 8 imagery, Tsou et al. (2017) [15] assessed the SUHI of Shenzen and Hong Kong based on 4 Landsat 8 images, and Kaplan et al. (2018) [14] explored the case study of the Skopje SUHI using only 2 July images. The value of such investigations on the urban climate is doubtless, but one should also acknowledge the shortcomings of the results due to the limited number of samples.
Comparatively, this study addresses the need for temporal and spatial continuity of remote sensing data, and it explores the climatology of the LST in a large urban area (Bucharest, Romania) based on 94 high-spatial-resolution images retrieved from Landsat 8. We used the Data INterpolating Empirical Orthogonal Functions (DINEOF) algorithm [19] in order to solve the inherent problem of missing data within satellite images, so that the exploratory study is ultimately based on a gap-free data set. Zhou et al. (2017) [20] showed that the DINEOF reconstruction method can capture the impact of land cover types on LST, pledging for a reasonable spatial pattern, which is particularly important in urban climatology. The temporal extent and the data objectively available for this study support a methodological approach, which can certainly be extended when more data are collected in the future over the same area. In the end, the seasonal and annual variations of the LST were explored.
High-spatial-resolution data sets with full coverage over an urban area have multiple applications beyond scientific research. For example, the temperature distribution over smaller administrative units within a city can provide useful information for urbanism, health risk assessment, or building industry. In this respect, we illustrate the distribution of the LST values over census units of Bucharest.
The manuscript is structured in four sections, as follows: After the introduction (1), we briefly present relevant geographical and climatic facts about the study area, and we detail the data and methods (2), which fundament the results (3), and we supply a set of concluding remarks (4).

2. Materials and Methods

2.1. Study Area

The case study focuses on Bucharest, the capital and the largest city of Romania, with an estimated population of about two million inhabitants [21], lying over approximately 240 km2. The climate of Bucharest is monitored by three WMO stations, namely one ‘urban’ weather station, i.e., București-Filaret, placed within the city limits; and two ‘peri-urban’ weather stations, i.e., București-Băneasa, at 10 km N of the downtown, and București-Afumați, at approximately 11.5 km NE of the downtown (Figure 1). According to the Köppen–Geiger climate classification [22], Bucharest has a hot-summer humid continental climate (Dfa) with the coldest month, January, averaging below 0 °C, while in July and August, the average temperature is above 22 °C, and above 10 °C from April to October. The wettest period is April–July (Figure 2).

2.2. Data and Methods

The Landsat 8 mission provides timely high-quality visible and infrared images, sufficiently consistent with other satellite data in terms of acquisition geometry, calibration, coverage, and spectral characteristics [23]. We used the LST derived from the bands 10 (10.60–11.19 µm) and 11 (11.50–12.51 µm), resampled at 30 m, from Landsat 8 TIRS (Thermal Infrared Sensors) instruments. The Landsat 8 TIRS products use split window algorithms and techniques for correcting atmospheric disturbances, such as absorption and emission, or surface emissivity inferred from MODIS land-cover calculations. Emissivity is a critical variable for the LST estimation. This study used Landsat 8 LST with NDVI-based emissivity, estimated from the Landsat visible and near-infrared bands and typical emissivity values, retrieved from http://rslab.gr/downloads.html, with full technical details available online [13].
The scenes were retrieved between 08:58 and 09:04 UTC, and the area of interest covers the administrative perimeter of Bucharest and its surroundings within a rectangle ranging between 25.90° and 26.32° East, and 44.32° and 44.59° North. This study was based on 94 Landsat 8 imagery ranging between 2013 and 2018, with an average percentage of data coverage of 91.4% (Table 2). Table 3 shows the degree of completeness of the 94 images when downloaded. In order to secure the quality of the results and to minimize the sampling and processing errors, the data beyond the 1st and 99th percentiles were filtered out.
Missing data is a major barrier for satellite meteorology and especially for climate applications, which require long-term and good spatial coverage of information, and constant efforts address this issue. Henn et al. (2013) [24] compared the performance of five techniques used to fill in missing temperature data, namely (a) spatiotemporal correlations based on empirical orthogonal functions (EOFs), (b) time series diurnal interpolation, and (c, d, e) three variations of lapse rate-based filling. They found that the spatiotemporal correlations using EOF reconstruction were most accurate for a large number of stations and missing data. Long et al. (2020) [25] combined MODIS and SEVIRI LST in order to generate a complete daytime data set, and Zhao et al. (2020) [26] also used MODIS to obtain all-weather conditions data. However, high-spatial-resolution data sets allow in-depth analysis of the LST at an urban and intra-urban scale. Considering the results provided by Henn et al. (2013), this study addressed such limitations by reconstructing complete LST data sets for the selected Landsat images through 2013–2018 using the DINEOF algorithm [27,28,29]. The selection of this method was justified by its relatively simple application in situations when relevant co-variables are not available.
Essentially, the missing LST values of each Landsat 8 image were reconstructed using the function DINEOF implemented in sinkr R package [30]. This method does not require a priori knowledge about the statistics of the full data set [31], which is an advantage for analyzing extensive data sets.
The DINEOF method consists of an iterative method to calculate the field values at missing positions. It implies the application of the following routine [19,29,32]:
  • The spatial and temporal mean of the observation data are removed from the raw LST dataset.
  • The ‘no observation’ pixels are replaced with zero values.
  • The resulting dataset is used to compute the first EOF, and the values obtained during the EOF decomposition are used to replace the missing data.
  • Sequential EOFs are calculated iteratively until a user-defined convergence criterion is reached.
  • The procedure is repeated by computing the two EOFs, three EOFs, etc.
  • The total number of EOFs is determined by the results of the cross-validation procedure, commonly checked with 1% of the valid data selected at the beginning of the procedure.
The use of only one selected EOF configuration may be considered a limitation of the DINEOF algorithm [33,34], but the accuracy of the results reported here pledge for applicability in urban climate research. Overall, the cross-validation pixels were utilized to calculate the accuracy by comparing the pixels of the raw data sets with the pixels of the filled data sets. Figure 3 exemplifies the visual performance of the DINEOF method for filling in the missing LST values of two Landsat 8 images over the urban areas of Bucharest (Romania).
The complete working flow of this study, from retrieving the Landsat 8 LST images to potential applications of the resulted gap-free data set, is provided in Figure 4. The approach was applied here for the city of Bucharest, but it is clear that a similar flow would be applicable for any urban area, and various applications may be proposed.

3. Results and Discussion

3.1. Gap Filling the Landsat 8 Land Surface Temperature Data Set: Results and Validation

By applying the DINEOF gap-filling method, we obtained 94 Landsat 8 images with full coverage of the study area. Between 2013 and 2018, the annual number of available images ranges between 13 and 21, while the monthly number of images varies between 2 in February, and 13 in July and August (Figure 5). More frequent images are available during the warm season (i.e., 9 to 13 images from March to October) due to the lower cloudiness.
In order to evaluate the accuracy of the DINEOF gap-filling method, we artificially simulated gaps in the original LST data set, and the estimated values were compared to the raw LST values. The artificial gaps were created on a subset representing 50% of the selected LST images, and 1000 randomly selected pixels were assigned as not available (NA) for each image. The DINEOF gap-filling method was tested on the entire data set, namely on all the images containing artificially created gaps. Figure 6 shows the relationship between estimated and original LST values. One can notice that the DINEOF algorithm results in a gap-filled LST data set that is very well correlated and statistically consistent with the initial LST data set, i.e., Pearson’s correlation coefficient r2 = 0.979, and only −0.3 °C difference between the average values (Table 4).
The performance of the matching between the gap-filled and raw LST data sets was also summarized in terms of the correlation, root-mean-square (RMS) errors, and amplitude of their variance (standard deviations) using a Taylor diagram [35], computed for four distinct land-cover categories derived from the Urban Atlas LCLU 2012 (https://land.copernicus.eu/local/urban-atlas/urban-atlas-2018), namely urban, rural, forest, and water (Figure 7). One can indicate the following deduction: (a) The performance of the DINEOF method is very good and similar for the land-cover categories (i.e., very high correlation coefficients, and low RMS errors); (b) based on the standard deviation values, the gap-filled data are closer to the raw data for land-cover categories closer to nature (i.e., forest and water) than for the more anthropic ones (i.e., rural and urban); and (c) there is a clear distinction between the more natural categories and more anthropic ones in terms of RMS errors, but the values are low in all the cases (±2.0 °C).

3.2. Climatic Analysis of the Land Surface Temperature over Bucharest Using the Gap-Filled Landsat 8 Data Set

Climate research requires long-term data and full spatial coverage, if possible. While a 30-year period is recommended for climate prediction purposes, shorter time intervals may perform as effectively as 30-year averaging periods and provide useful overall climate information [36]. It is undoubtedly an advantage to have early climate information over an area even if it is consequently from shorter periods, than to delay climate research and wait for the completion of a 30-year period of data. In this respect, the spatial completeness and the temporal extent of the reconstructed Landsat 8 LST data series supports a preliminary climatic analysis over Bucharest at monthly, seasonal, and annual scales.
Figure 8 shows the average LST values through May–September, namely the months with more than 9 images each along the period 2013–2018. Figure 9, Figure 10 and Figure 11 illustrate the seasonal and, respectively, annual and multi-annual LST averages integrating all the images available over the period analyzed in this study. One can remark that the LST seasonality is perfectly captured by the Landsat data (Figure 8 and Figure 9). For example, June, July, and August (JJA) are the hottest months; the LST values decrease in spring (March, April, and May—MAM) and autumn (September, October, and November—SON); and winter is the coldest season (December, January, and February—DJF). Moreover, this is consistent with the thermal climate over the area of interest, as described in Section 2.1. Mean daily LSTs above 30 °C prevail from May to August, while 40–44 °C are common LSTs over the urban area of Bucharest during the daytime in July (Figure 8). In the central part of the city, the multiannual average LST values of the warm seasons range between 22 and 27 °C, and over the urban periphery the LST is 20–22 °C (Figure 11). The estimated SUHI intensity of 2.0–5.0 °C is in perfect agreement with previous work based on MODIS LST products [37].
One can remark that the spatial pattern of the LST (Figure 8, Figure 9, Figure 10 and Figure 11) is strongly connected with the land cover-land use characteristics of the urban area (Figure 1) for all the temporal scales tackled in this study. The warmest areas are concentrated in the central part Bucharest, overlapping the urban fabric districts with high building density, but spots with high LST values occur towards the edges of the administrative perimeter too, over industrial or residential urban fabric. The water and forest surfaces may be 8–10 °C colder than the urban fabric in terms of the multi-annual average (Figure 11).
In order to confirm the accuracy of the method and the reliability of the results, the Landsat 8 LST values were compared with the corresponding air temperature retrieved at the same time of the day from the pixels containing the three WMO meteorological stations of Bucharest (i.e., București-Afumați, -Băneasa, and -Filaret). According to Jin and Dickinson (2010) [38], the difference LST–Ta is higher at noon (i.e., 15 °C), and lower by nighttime (i.e., <5 °C), while Mbuh et al. (2019) [39] found differences of up to 5 °C in Chicago and Minneapolis, based on Landsat 4, 5, and 7 images from 1984–2016. For Bucharest, the LST values retrieved from Landsat 8 OLI and TIRS over the pixels corresponding to the weather stations București-Filaret, -Băneasa, and -Afumați are higher than Ta, with 0.1 to 4.0 °C in 30% of the cases, and 4.1 to 6.0 °C in almost 30% of the cases (Figure 12). One can notice a strong correlation between LST and Ta, with Pearson’s correlation coefficients (R2) above 0.9 over each of the three meteorological stations analyzed here (Figure 13).
The gap-filled high-spatial-resolution LST data set based on the Landsat 8 imagery can be combined with other information and derive products that are very useful in different applications. For example, the distribution of the LST over census units of Bucharest (Figure 14) is fundamental information for assessing the thermal hazard risk at a fine scale, and it will be investigated as a follow-up of this study. Such details cannot be retrieved unless high-spatial-resolution data, such as the one obtained from gap-filling Landsat 8 imagery, is available.
One could summarize several clear benefits and inherent limitations related to the DINEOF-based gap filling of satellite imagery data, i.e., Landsat 8. The main benefits consist of (1) the delivery of a data set at high spatial resolution, (2) with full coverage over remote and heterogeneous areas where in situ weather stations’ measurements are lacking or are not continuous, which are (3) obtained at a relatively low cost for the end user [40]. The main advantage of using the DINEOF gap-filling procedure is that the method is easily applicable and does require supplementary variables (4). The coarse temporal resolution when using Landsat 8 imagery is an insurmountable barrier for some applications, such as operational forecasting, monitoring the rapid development of phenomena, or analysis of nighttime processes. However, the Landsat 8 data sets can be used for climate monitoring or risk studies related to more stable variables, such as LST [41].

4. Conclusions

Gap-free satellite remote sensing products at a fine resolution may be an excellent compromise between the need for full spatial coverage and temporal continuity of climate data in urban areas. The results of this study demonstrated that 30-m-spatial-resolution Landsat 8 imagery can be extremely useful for retrieving the LST in urban areas, despite the spatial and temporal discontinuity of the data sets. Although missing data, due to factors like cloudiness or a limited number of satellite passages, has been an important barrier for the proper use of Landsat LST in urban climate research, this study employed an efficient solution for obtaining more extended and better data sets, regarding both temporal and spatial coverage. This is an important advantage, especially in remote or heterogeneous areas, where filling the observational spatiotemporal gaps in data becomes more crucial [40]. This study demonstrated the advantage of applying the DINEOF method for filling LST gaps in satellite imagery in order to take full advantage of the high spatial resolution of the Landsat 8 data sets.
The DINEOF gap filling algorithm was applied to each Landsat 8 image with at least 40% valid LST values over Bucharest (Romania), and generated a consistent data set of 94 images with complete spatial coverage in the urban area through 2013–2018. The DINEOF procedure was validated by filling artificially created gaps in Landsat 8 images, and evaluating the results against the initial values in terms of statistic parameters, such as the correlation, RMS error, and variance. The returned LST values corresponding to the artificial gaps were found to be very well correlated and statistically consistent with the original data, pledging for an efficient gap-filling procedure. The land cover biases the performance of the gap filling, and the method performed slightly better for natural land cover categories, very likely due to their higher temperature homogeneity, but the results were very similar for all the categories.
The climatic analysis of the gap-free LST data set illustrated the role of the geographical setting and urban land-cover on the local climate. The comparison between LST and Ta at three WMO stations monitoring the climate of Bucharest (i.e., București-Afumați, -Băneasa, and -Filaret) returned strong correlation coefficients (R2 > 0.9) and approximately 70% of the differences were less than 6 °C, in very good agreement with the previous studies.
Further research may be envisaged aiming to complete this study with other data retrieved from sources like the updated Landsat 8, previous Landsat or other missions, ground-based data, modelling outputs, and ancillary data. Relevant improvements of the outputs in terms of the accuracy may be pursued by more complex validation campaigns using ground-based LST measurements and other satellite products. The LST distribution over census units of Bucharest exemplifies that by combining (1) high-spatial-resolution Landsat 8 images, with full urban coverage, and (2) detailed ground information, one can derive very useful products and applications.

Author Contributions

The authors equally contributed to the development of this study, as follows: Conceptualization, S.C., A.D., V.-A.A.; methodology, S.C., A.D., V.-A.A.; software, S.C., A.D., V.-A.A.; validation, S.C., A.D., V.-A.A.; formal analysis, S.C., A.D., V.-A.A.; investigation, S.C., A.D., V.-A.A.; resources, S.C., A.D., V.-A.A.; data curation, S.C., A.D., V.-A.A.; writing—original draft preparation, S.C., A.D., V.-A.A.; writing—review and editing, S.C., A.D., V.-A.A.; visualization, S.C., A.D., V.-A.A.; supervision, S.C., A.D., V.-A.A.; project administration, S.C., A.D., V.-A.A.; funding acquisition, S.C., A.D. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by a grant of Ministry of Research and Innovation, Romania, CNCS-UEFISCDI, project number PN-III-P1-1.1-PD-2016-1579, within PNCDI III.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

  1. Stewart, I.D.; Oke, T.R. Local Climate Zones for Urban Temperature Studies. Bull. Am. Meteorol. Soc. 2012, 93, 1879–1900. [Google Scholar] [CrossRef]
  2. Bivand, R.S.; Pebesma, E.J.; Gomez-Rubio, V. Applied Spatial Data Analysis with R; Springer: New York, NY, USA, 2008; ISBN 978-1-4614-7618-4. [Google Scholar]
  3. Demuzere, M.; Bechtel, B.; Middel, A.; Mills, G. Mapping Europe into local climate zones. PLoS ONE 2019, 14, e0214474. [Google Scholar] [CrossRef] [Green Version]
  4. Muller, C.L.; Chapman, L.; Johnston, S.; Kidd, C.; Illingworth, S.; Foody, G.; Overeem, A.; Leigh, R.R. Crowdsourcing for climate and atmospheric sciences: Current status and future potential. Int. J. Climatol. 2015, 35, 3185–3203. [Google Scholar] [CrossRef] [Green Version]
  5. Baklanov, A.; Grimmond, C.S.B.; Carlson, D.; Terblanche, D.; Tang, X.; Bouchet, V.; Lee, B.; Langendijk, G.; Kolli, R.K.; Hovsepyan, A. From urban meteorology, climate and environment research to integrated city services. Urban Clim. 2018, 23, 330–341. [Google Scholar] [CrossRef]
  6. Sfîcă, L.; Ichim, P.; Apostol, L.; Ursu, A. The extent and intensity of the urban heat island in Iași city, Romania. Theor. Appl. Climatol. 2018, 134, 777–791. [Google Scholar] [CrossRef]
  7. Cheval, S.; Dumitrescu, A. Rapid daily and sub-daily temperature variations in an urban environment. Clim. Res. 2017, 73, 233–246. [Google Scholar] [CrossRef]
  8. Overeem, A.; Robinson, J.C.R.; Leijnse, H.; Steeneveld, G.-J.; Horn, B.K.P.; Uijlenhoet, R. Crowdsourcing urban air temperatures from smartphone battery temperatures. Geophys. Res. Lett. 2013, 40, 4081–4085. [Google Scholar] [CrossRef]
  9. Ichim, P.; Sfîcă, L.; Abid, A.; Ursu, A.; Jitariu, V. Characteristics of Nocturnal Urban Heat Island of Iaşi During a Summer Heat Wave (1–6 of August 2017). Aerul Apa Compon. Mediu. 2018, 253–260. [Google Scholar] [CrossRef] [Green Version]
  10. Oscar, W.M.O. OSCAR Observing Systems Capability Analysis and Review Tool. Available online: https://www.wmo-sat.info/oscar/ (accessed on 20 July 2020).
  11. Oke, T.R.; Mills, G.; Christen, A.; Voogt, J.A. Urban Climates; Cambridge University Press: Cambridge, UK, 2017; ISBN 978-0-521-84950-0. [Google Scholar]
  12. Liu, L.; Zhang, Y. Urban heat island analysis using the Landsat TM data and ASTER data: A case study in Hong Kong. Remote Sens. 2011, 3, 1535–1552. [Google Scholar] [CrossRef] [Green Version]
  13. Parastatidis, D.; Mitraka, Z.; Chrysoulakis, N.; Abrams, M. Online global land surface temperature estimation from landsat. Remote Sens. 2017, 9, 1208. [Google Scholar] [CrossRef] [Green Version]
  14. Kaplan, G.; Avdan, U.; Avdan, Z.Y. Urban heat island analysis using the landsat 8 satellite data: A case study in Skopje, Macedonia. Multidiscip. Digit. Publ. Inst. Proc. 2018, 2, 358. [Google Scholar] [CrossRef] [Green Version]
  15. Tsou, J.; Zhuang, J.; Li, Y.; Zhang, Y. Urban heat island assessment using the Landsat 8 data: A case study in Shenzhen and Hong Kong. Urban Sci. 2017, 1, 10. [Google Scholar] [CrossRef]
  16. Grigoraș, G.; Urițescu, B. Land Use/Land Cover changes dynamics and their effects on Surface Urban Heat Island in Bucharest, Romania. Int. J. Appl. Earth Obs. Geoinf. 2019, 80, 115–126. [Google Scholar] [CrossRef]
  17. Cristóbal, J.; Jiménez-Muñoz, J.C.; Sobrino, J.A.; Ninyerola, M.; Pons, X. Improvements in land surface temperature retrieval from the Landsat series thermal band using water vapor and air temperature. J. Geophys. Res. Atmos. 2009, 114, D08103. [Google Scholar] [CrossRef]
  18. Lemus-Canovas, M.; Martin-Vide, J.; Moreno-Garcia, M.C.; Lopez-Bustins, J.A. Estimating Barcelona’s metropolitan daytime hot and cold poles using Landsat-8 Land Surface Temperature. Sci. Total Environ. 2020, 699, 134307. [Google Scholar] [CrossRef]
  19. Alvera-Azcárate, A.; Barth, A.; Sirjacobs, D.; Lenartz, F.; Beckers, J.-M. Data Interpolating Empirical Orthogonal Functions (DINEOF): A tool for geophysical data analyses. Mediterr. Mar. Sci. 2011, 12, 5–11. [Google Scholar] [CrossRef] [Green Version]
  20. Zhou, W.; Peng, B.; Shi, J. Reconstructing spatial–temporal continuous MODIS land surface temperature using the DINEOF method. J. Appl. Remote Sens. 2017, 11, 046016. [Google Scholar] [CrossRef]
  21. National Institute of Statistics. Available online: http://statistici.insse.ro:8077/tempo-online (accessed on 10 January 2020).
  22. Fick, S.E.; Hijmans, R.J. WorldClim 2: New 1-km spatial resolution climate surfaces for global land areas. Int. J. Climatol. 2017, 37, 4302–4315. [Google Scholar] [CrossRef]
  23. Ihlen, V. Landsat 8 (L8) Data Users Handbook; U.S. Geological Survey: Reston, VA, USA, 2019; Available online: https://prd-wret.s3-us-west-2.amazonaws.com/assets/palladium/production/atoms/files/LSDS-1574_L8_Data_Users_Handbook-v5.0.pdf (accessed on 1 August 2020).
  24. Henn, B.; Raleigh, M.S.; Fisher, A.; Lundquist, J.D. A Comparison of Methods for Filling Gaps in Hourly Near-Surface Air Temperature Data. J. Hydrometeorol. 2013, 14, 929–945. [Google Scholar] [CrossRef]
  25. Long, D.; Yan, L.; Bai, L.; Zhang, C.; Li, X.; Lei, H.; Yang, H.; Tian, F.; Zeng, C.; Meng, X.; et al. Generation of MODIS-like land surface temperatures under all-weather conditions based on a data fusion approach. Remote Sens. Environ. 2020, 246, 111863. [Google Scholar] [CrossRef]
  26. Zhao, W.; Duan, S.-B. Reconstruction of daytime land surface temperatures under cloud-covered conditions using integrated MODIS/Terra land products and MSG geostationary satellite data. Remote Sens. Environ. 2020, 247, 111931. [Google Scholar] [CrossRef]
  27. Wilks, D.S. Statistical Methods in the Atmospheric Sciences. In International Geophysics; Wilks, D.S., Ed.; Academic Press: Cambridge, MA, USA, 2011; Volume 100, pp. 2–676. ISBN 0074-6142. [Google Scholar]
  28. Taylor, M.H.; Losch, M.; Wenzel, M.; Schröter, J. On the Sensitivity of Field Reconstruction and Prediction Using Empirical Orthogonal Functions Derived from Gappy Data. J. Clim. 2013, 26, 9194–9205. [Google Scholar] [CrossRef] [Green Version]
  29. Beckers, J.M.; Rixen, M. EOF Calculations and Data Filling from Incomplete Oceanographic Datasets. J. Atmos. Ocean. Technol. 2003, 20, 1839–1856. [Google Scholar] [CrossRef]
  30. Taylor, M.H. Sinkr: Collection of Functions with Emphasis in Multivariate Data Analysis 2017. R Package Version 0.6. Available online: https://github.com/marchtaylor/sinkr (accessed on 20 July 2020).
  31. Weiss, D.J.; Atkinson, P.M.; Bhatt, S.; Mappin, B.; Hay, S.I.; Gething, P.W. An effective approach for gap-filling continental scale remotely sensed time-series. ISPRS J. Photogramm. Remote Sens. 2014, 98, 106–118. [Google Scholar] [CrossRef] [Green Version]
  32. Alvera-Azcárate, A.; Barth, A.; Parard, G.; Beckers, J.-M. Analysis of SMOS sea surface salinity data using DINEOF. Remote Sens. Environ. 2016, 180, 137–145. [Google Scholar] [CrossRef] [Green Version]
  33. Sirjacobs, D.; Alvera-Azcárate, A.; Barth, A.; Lacroix, G.; Park, Y.; Nechad, B.; Ruddick, K.; Beckers, J.-M. Cloud filling of ocean colour and sea surface temperature remote sensing products over the Southern North Sea by the Data Interpolating Empirical Orthogonal Functions methodology. J. Sea Res. 2011, 65, 114–130. [Google Scholar] [CrossRef]
  34. Nechad, B.; Alvera-Azcaràte, A.; Ruddick, K.; Greenwood, N. Reconstruction of MODIS total suspended matter time series maps by DINEOF and validation with autonomous platform data. Ocean Dyn. 2011, 61, 1205–1214. [Google Scholar] [CrossRef] [Green Version]
  35. Taylor, K.E. Summarizing multiple aspects of model performance in a single diagram. J. Geophys. Res. Atmos. 2001, 106, 7183–7192. [Google Scholar] [CrossRef]
  36. Trewin, B.C. The Role of Climatological Normals in a Changing Climate; WCDMP-No. 61; WMO/TD-No. 1377; World Meteorological Organization: Geneva, Switzerland, 2007. [Google Scholar]
  37. Cheval, S.; Dumitrescu, A. The summer surface urban heat island of Bucharest (Romania) retrieved from MODIS images. Theor. Appl. Climatol. 2015, 121, 631–640. [Google Scholar] [CrossRef]
  38. Jin, M.; Dickinson, R.E. Land surface skin temperature climatology: Benefitting from the strengths of satellite observations. Environ. Res. Lett. 2010, 5, 44004. [Google Scholar] [CrossRef] [Green Version]
  39. Mbuh, M.J.; Wheeler, R.; Cook, A. Spatiotemporal analysis of urban heat island intensification in the city of Minneapolis-St. Paul and Chicago metropolitan areas using Landsat data from 1984 to 2016. Geocarto Int. 2019, 1–26. [Google Scholar] [CrossRef]
  40. Singh, S.; Bhardwaj, A.; Singh, A.; Sam, L.; Shekhar, M.; Martín-Torres, F.J.; Zorzano, M.-P. Quantifying the Congruence between Air and Land Surface Temperatures for Various Climatic and Elevation Zones of Western Himalaya. Remote Sens. 2019, 11, 2889. [Google Scholar] [CrossRef] [Green Version]
  41. Cheval, S.; Micu, D.; Dumitrescu, A.; Irimescu, A.; Frighenciu, M.; Iojă, C.; Tudose, N.C.; Davidescu, Ș.; Antonescu, B. Meteorological and Ancillary Data Resources for Climate Research in Urban Areas. Climate 2020, 8, 37. [Google Scholar] [CrossRef] [Green Version]
Figure 1. Urban administrative limit and functional urban areas (FAU) of Bucharest. (Source: Urban Atlas LCLU 2012, available online at <https://land.copernicus.eu/local/urban-atlas/urban-atlas-2012>).
Figure 1. Urban administrative limit and functional urban areas (FAU) of Bucharest. (Source: Urban Atlas LCLU 2012, available online at <https://land.copernicus.eu/local/urban-atlas/urban-atlas-2012>).
Sensors 20 05336 g001
Figure 2. Average monthly air temperature and precipitation amounts at Bucharest (1961–2018).
Figure 2. Average monthly air temperature and precipitation amounts at Bucharest (1961–2018).
Sensors 20 05336 g002
Figure 3. Land surface temperature (LST) (°C) over Bucharest (Romania) as retrieved from raw and gap-filled Landsat 8 images for 23 April 2013 (a) and 25 June 2016 (b). White spots correspond to missing data.
Figure 3. Land surface temperature (LST) (°C) over Bucharest (Romania) as retrieved from raw and gap-filled Landsat 8 images for 23 April 2013 (a) and 25 June 2016 (b). White spots correspond to missing data.
Sensors 20 05336 g003
Figure 4. Workflow from raw Landsat 8 LST data to applications based on gap-free LST in an urban area.
Figure 4. Workflow from raw Landsat 8 LST data to applications based on gap-free LST in an urban area.
Sensors 20 05336 g004
Figure 5. Absolute and relative frequencies of Landsat 8 LST images and data available over the study area through 2013–2018: monthly (A) and annual (B) statistics.
Figure 5. Absolute and relative frequencies of Landsat 8 LST images and data available over the study area through 2013–2018: monthly (A) and annual (B) statistics.
Sensors 20 05336 g005
Figure 6. Comparison between DINEOF-filled LST and raw LST data over the validation sample. The boxplots depict the statistical properties of the two data sets, i.e., median, 25th, 75th percentile (the lower and upper hinges), and the 1.5 multiplied with the interquartile range (the upper and the lower whiskers).
Figure 6. Comparison between DINEOF-filled LST and raw LST data over the validation sample. The boxplots depict the statistical properties of the two data sets, i.e., median, 25th, 75th percentile (the lower and upper hinges), and the 1.5 multiplied with the interquartile range (the upper and the lower whiskers).
Sensors 20 05336 g006
Figure 7. Statistical summary of the matching performance obtained using the DINEOF gap-filling method. The gap-filled data set was compared to observations using a validation subset containing 50% of the selected LST images, and 1000 randomly selected pixels assigned as NA for each image.
Figure 7. Statistical summary of the matching performance obtained using the DINEOF gap-filling method. The gap-filled data set was compared to observations using a validation subset containing 50% of the selected LST images, and 1000 randomly selected pixels assigned as NA for each image.
Sensors 20 05336 g007
Figure 8. Average monthly LST values (°C) over Bucharest retrieved from Landsat 8 imagery (2013–2018).
Figure 8. Average monthly LST values (°C) over Bucharest retrieved from Landsat 8 imagery (2013–2018).
Sensors 20 05336 g008
Figure 9. Average seasonal LST values (°C) over Bucharest retrieved from Landsat 8 imagery (2013–2018).
Figure 9. Average seasonal LST values (°C) over Bucharest retrieved from Landsat 8 imagery (2013–2018).
Sensors 20 05336 g009
Figure 10. Average summer LST values (°C) over Bucharest retrieved from JJA Landsat 8 imagery (2013–2018).
Figure 10. Average summer LST values (°C) over Bucharest retrieved from JJA Landsat 8 imagery (2013–2018).
Sensors 20 05336 g010
Figure 11. Multi-annual average LST over Bucharest during the warm season (April–September) retrieved from Landsat 8 imagery (2013–2018).
Figure 11. Multi-annual average LST over Bucharest during the warm season (April–September) retrieved from Landsat 8 imagery (2013–2018).
Sensors 20 05336 g011
Figure 12. Frequency of the differences between Ta and the corresponding Landsat 8 LST values retrieved over the pixels containing the Bucharest weather stations (2013–2018).
Figure 12. Frequency of the differences between Ta and the corresponding Landsat 8 LST values retrieved over the pixels containing the Bucharest weather stations (2013–2018).
Sensors 20 05336 g012
Figure 13. Ta versus LST values retrieved from Landsat 8 over the pixels corresponding to the Bucharest weather stations (2013–2018).
Figure 13. Ta versus LST values retrieved from Landsat 8 over the pixels corresponding to the Bucharest weather stations (2013–2018).
Sensors 20 05336 g013
Figure 14. Daytime average Landsat 8-based LST (°C) over census units of Bucharest in July (2013–2018).
Figure 14. Daytime average Landsat 8-based LST (°C) over census units of Bucharest in July (2013–2018).
Sensors 20 05336 g014
Table 1. Characteristics of several satellite remote sensing products delivering LST data.
Table 1. Characteristics of several satellite remote sensing products delivering LST data.
SensorSatelliteSpatial ResolutionTemporal ResolutionTime Span
SEVIRIMSG3 to 5 km15-min1983 to date
AVHRRNOAA1.1 km2 images/24 h1981 to date
MODISTerra/Aqua1 km4 images/24 h2000/2002 to date
SLSTRCopernicus Sentinel-31 km1 image/24 h2017 to date
TM, ETM+, OLI, TIRSLandsat 4, 5, 7, 830 m (resampled)1 image/8 or 16 days1982 to date
Table 2. Number of images used and average percentage of data coverage over the study area.
Table 2. Number of images used and average percentage of data coverage over the study area.
Year201320142015201620172018Total
Number of images13141321191494
Average percentage of data coverage (%)91.494.793.088.590.090.791.4
Table 3. Percentage of LST data within the study area available from the selected Landsat 8 images.
Table 3. Percentage of LST data within the study area available from the selected Landsat 8 images.
Percentage of Data Coverage (%)40.1–50.050.1–60.060.1–70.070.1–80.080.1–90.090.1–100.0
Number of images20171668
Table 4. Summary statistics of the raw and DINEOF gap-filled LST data sets.
Table 4. Summary statistics of the raw and DINEOF gap-filled LST data sets.
Statistical ParameterRaw Data Set LST (°C)Gap-Filled Data Set LST (°C)Difference between Raw and Gap-Filled Data Sets (°C)
Minimum−0.9−2.61.7
1st Quartile21.521.9−0.4
Median26.826.9−0.2
Average26.226.5−0.3
3rd Quartile32.733.0−0.3
Maximum53.651.32.3

Share and Cite

MDPI and ACS Style

Cheval, S.; Dumitrescu, A.; Amihaesei, V.-A. Exploratory Analysis of Urban Climate Using a Gap-Filled Landsat 8 Land Surface Temperature Data Set. Sensors 2020, 20, 5336. https://doi.org/10.3390/s20185336

AMA Style

Cheval S, Dumitrescu A, Amihaesei V-A. Exploratory Analysis of Urban Climate Using a Gap-Filled Landsat 8 Land Surface Temperature Data Set. Sensors. 2020; 20(18):5336. https://doi.org/10.3390/s20185336

Chicago/Turabian Style

Cheval, Sorin, Alexandru Dumitrescu, and Vlad-Alexandru Amihaesei. 2020. "Exploratory Analysis of Urban Climate Using a Gap-Filled Landsat 8 Land Surface Temperature Data Set" Sensors 20, no. 18: 5336. https://doi.org/10.3390/s20185336

APA Style

Cheval, S., Dumitrescu, A., & Amihaesei, V. -A. (2020). Exploratory Analysis of Urban Climate Using a Gap-Filled Landsat 8 Land Surface Temperature Data Set. Sensors, 20(18), 5336. https://doi.org/10.3390/s20185336

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop