Sunglint Detection for Unmanned and Automated Platforms

Garaba, Shungudzemwoyo P.; Schulz, Jan; Wernand, Marcel Robert

doi:10.3390/s120912545

Cited by 30 publications

(27 citation statements)

References 33 publications

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“…It is presumed that perceived color of seawater in the NWES is strongly driven by CDOM and SPM although chl-a plays a seasonal and local role for example in the Central North Sea [32][33][34][35]. In situ station (blue dots) sampling was done in the German Bight (1)(2)(3)(4)(5)(6)(7)(8), North Sea (9-26), Inner Seas (27)(28)(29)(30)(31)(32)(33)(34), Irish Sea (35)(36)(37)(38)(39)(40)(41)(42)(43), and Celtic Sea (44)(45)(46)(47)(48)(49)(50)(51)(52)(53)(54)(55)(56)(57)(58)(59)(60). Region naming is based on maps from The Germany Federal Maritime and Hydrographic Agency [34] and International Hydrographic Organization [35].…”

Section: Study Areamentioning

confidence: 99%

Section: Underway Sampling Remote Sensing Reflectancementioning

confidence: 99%

“…A detailed description of the instrumental setup and quality control of measurements is presented in a previous study [36]. The quality control involved eliminating contaminated measurements, i.e., those taken at dusk and dawn before significant incoming solar radiation could be detected, under rainfall, or with excessive glint as detected by an image algorithm [36]. To compute water leaving radiance L W (θ sfc , Φ, λ) and remote sensing reflectance R RS (θ, Φ, λ), surface reflected glint correction was implemented according to a recent protocol [37] with the basic Equation (1):…”

Section: Underway Sampling Remote Sensing Reflectancementioning

confidence: 99%

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Physical, Bio-Optical State and Correlations in North–Western European Shelf Seas

2014

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Abstract:Color of seawater has become an integral tool in understanding surface marine ecosystems and processes. In this paper we seek to assess the correlations and consequently the potential of using shipborne remote sensing products to infer marine environmental parameters. Typical seawater parameters are chlorophyll-a (chl-a), colored dissolved organic material (CDOM), suspended particulate material (SPM), Secchi-disk depth (SDD), temperature, and salinity. These parameters and radiometric quantities were observed from a total of 60 stations covering German Bight, North Sea, Inner Seas, Irish Sea, and Celtic Sea. Bio-optical models developed in this study were used to predict the in situ measured parameters, with low mean unbiased percent differences and absolute percent difference less than 35%. Our investigations show that the use of ocean color products namely the Forel-Ule Index to infer seawater parameters is encouraging. The constrained spatial and temporal span of measured in situ parameters does limit the accuracy of our models. Absorption coefficients of the main color producing agents CDOM, chl-a, and inorganic fraction of SPM (iSPM) were determined to estimate absorption budgets. During the field campaign, iSPM was the primary light absorber over the spectral range (400-700 nm) although variabilities were observed in the regional seas.

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Section: Study Areamentioning

confidence: 99%

Section: Underway Sampling Remote Sensing Reflectancementioning

confidence: 99%

Section: Underway Sampling Remote Sensing Reflectancementioning

confidence: 99%

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Physical, Bio-Optical State and Correlations in North–Western European Shelf Seas

2014

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“…Sunglint is a transient anomaly that occurs when sunlight is reflected from the seawater surface directly into the down looking optical sensor (Garaba et al, 2012). In order to eliminate this uncertainty in detecting impulse noise, sun glint was also detected using SWIR band (1.55 -1.75 microns) data of AWiFS sensor.…”

Section: Resultsmentioning

confidence: 99%

Automatic Assessment of Acquisition and Transmission Losses in Indian Remote Sensing Satellite Data

Roy¹,

Kumari²,

Sarma³

et al. 2016

ISPRS Ann. Photogramm. Remote Sens. Spatial Inf. Sci.

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The quality of Remote Sensing data is an important parameter that defines the extent of its usability in various applications. The data from Remote Sensing satellites is received as raw data frames at the ground station. This data may be corrupted with data losses due to interferences during data transmission, data acquisition and sensor anomalies. Thus it is important to assess the quality of the raw data before product generation for early anomaly detection, faster corrective actions and product rejection minimization. Manual screening of raw images is a time consuming process and not very accurate. In this paper, an automated process for identification and quantification of losses in raw data like pixel drop out, line loss and data loss due to sensor anomalies is discussed. Quality assessment of raw scenes based on these losses is also explained. This process is introduced in the data pre-processing stage and gives crucial data quality information to users at the time of browsing data for product ordering. It has also improved the product generation workflow by enabling faster and more accurate quality estimation.

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“…This has to be considered especially in mobile applications, where the covered scenes can change rapidly. In the case of interference, the video image information of sea surface conditions, like the presence of reflected sunlight, could even be useful for supplementary quality information and flagging criteria for above-water optical measurement systems (Garaba et al, 2012(Garaba et al, , 2013.…”

Section: Remote Sensing Of the Sea Surface Temperaturementioning

confidence: 99%

A research port test bed based on distributed optical sensors and sensor fusion framework for ad hoc situational awareness

Rüssmeier

Hahn

Nicklas

2017

J. Sens. Sens. Syst.

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Abstract. Maritime study sites utilized as a physical experimental test bed for sensor data fusion, communication technology and data stream analysis tools can provide substantial frameworks for design and development of e-navigation technologies. Increasing safety by observation and monitoring of the maritime environment by new technologies meets forward-looking needs to facilitate situational awareness. Further, such test beds offer a solid basis for standardizing new technologies to advance growth by reducing "time to market" of up-to-date industrial products and technologies. Especially optical sensor technologies are well suited to provide a situational and marine environmental assessment of waterways for (i) online detection of relevant situations, (ii) collection of data for further analysis and (iii) reuse of data, e.g. for training or testing of assistant systems. The test bed set-up has to consider maintainability, flexibility and extensibility for efficient test set-ups. This means that new use cases and applications within the test bed infrastructure, here presented by a research port, can be easily developed and extended by installing new sensors, actuators and software components. Furthermore, the system supports reliable remote communication between onshore and offshore participants. A series of in situ experiments at the research port of Bremerhaven and in other maritime environments were performed, representing applications and scenarios to demonstrate the capability for the proposed system framework and design.

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Sunglint Detection for Unmanned and Automated Platforms

Cited by 30 publications

References 33 publications

Physical, Bio-Optical State and Correlations in North–Western European Shelf Seas

Physical, Bio-Optical State and Correlations in North–Western European Shelf Seas

Automatic Assessment of Acquisition and Transmission Losses in Indian Remote Sensing Satellite Data

A research port test bed based on distributed optical sensors and sensor fusion framework for ad hoc situational awareness

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