This page has only limited features, please log in for full access.
Geographically weighted regression (GWR) introduces the distance weighted kernel function to examine the non-stationarity of geographical phenomena and improve the performance of global regression. However, GWR calibration becomes critical when using a serial computing mode to process large volumes of data. To address this problem, an improved approach based on the compute unified device architecture (CUDA) parallel architecture fast-parallel-GWR (FPGWR) is proposed in this paper to efficiently handle the computational demands of performing GWR over millions of data points. FPGWR is capable of decomposing the serial process into parallel atomic modules and optimizing the memory usage. To verify the computing capability of FPGWR, we designed simulation datasets and performed corresponding testing experiments. We also compared the performance of FPGWR and other GWR software packages using open datasets. The results show that the runtime of FPGWR is negatively correlated with the CUDA core number, and the calculation efficiency of FPGWR achieves a rate of thousands or even tens of thousands times faster than the traditional GWR algorithms. FPGWR provides an effective tool for exploring spatial heterogeneity for large-scale geographic data (geodata).
Dongchao Wang; Yi Yang; Agen Qiu; Xiaochen Kang; Jiakuan Han; Zhengyuan Chai. A CUDA-Based Parallel Geographically Weighted Regression for Large-Scale Geographic Data. ISPRS International Journal of Geo-Information 2020, 9, 653 .
AMA StyleDongchao Wang, Yi Yang, Agen Qiu, Xiaochen Kang, Jiakuan Han, Zhengyuan Chai. A CUDA-Based Parallel Geographically Weighted Regression for Large-Scale Geographic Data. ISPRS International Journal of Geo-Information. 2020; 9 (11):653.
Chicago/Turabian StyleDongchao Wang; Yi Yang; Agen Qiu; Xiaochen Kang; Jiakuan Han; Zhengyuan Chai. 2020. "A CUDA-Based Parallel Geographically Weighted Regression for Large-Scale Geographic Data." ISPRS International Journal of Geo-Information 9, no. 11: 653.
In order to realize the automatic and accurate recognition of shipwreck targets in side-scan sonar (SSS) waterfall images, a pipeline that contains feature extraction, selection, and shipwreck recognition, an AdaBoost model was constructed by sample images. Shipwreck targets are detected quickly by a nonlinear matching model, and a shipwreck recognition in SSS waterfall images are given, and according to a wide set of combinations of different types of these individual procedures, the model is able to recognize the shipwrecks accurately. Firstly, two feature-extraction methods suitable for recognizing SSS shipwreck targets from natural sea bottom images were studied. In addition to these two typical features, some commonly used features were extracted and combined as comprehensive features to characterize shipwrecks from various feature spaces. Based on Independent Component Analysis (ICA), the preferred features were selected from the comprehensive features, which avoid dimension disaster and improved the correct recognition rate. Then, the Gentle AdaBoost algorithm was studied and used for constructing the shipwreck target recognition model using sample images. Finally, a shipwreck target recognition process for the SSS waterfall image was given, and the process contains shipwreck target fast detection by a nonlinear matching model and accurate recognition by the Gentle AdaBoost recognition model. The results show that the correct recognition rate of the model for the sample image is 97.44%, while the false positive rate is 3.13% and the missing detection rate is 0. This study of a measured SSS waterfall image confirms the correctness of the recognition process and model.
Bangyan Zhu; Xiao Wang; Zhengwei Chu; Yi Yang; Juan Shi. Active Learning for Recognition of Shipwreck Target in Side-Scan Sonar Image. Remote Sensing 2019, 11, 243 .
AMA StyleBangyan Zhu, Xiao Wang, Zhengwei Chu, Yi Yang, Juan Shi. Active Learning for Recognition of Shipwreck Target in Side-Scan Sonar Image. Remote Sensing. 2019; 11 (3):243.
Chicago/Turabian StyleBangyan Zhu; Xiao Wang; Zhengwei Chu; Yi Yang; Juan Shi. 2019. "Active Learning for Recognition of Shipwreck Target in Side-Scan Sonar Image." Remote Sensing 11, no. 3: 243.
To capture both global stationarity and spatiotemporal non-stationarity, a novel mixed geographically and temporally weighted regression (MGTWR) model accounting for global and local effects in both space and time is presented. Since the constant and spatial-temporal varying coefficients could not be estimated in one step, a two-stage least squares estimation is introduced to calibrate the model. Both simulations and real-world datasets are used to test and verify the performance of the proposed MGTWR model. Additionally, an Akaike Information Criterion (AIC) is adopted as a key model fitting diagnostic. The experiments demonstrate that the MGTWR model yields more accurate results than do traditional spatially weighted regression models. For instance, the MGTWR model decreased AIC value by 2.7066, 36.368 and 112.812 with respect to those of the mixed geographically weighted regression (MGWR) model and by 45.5628, −38.774 and 35.656 with respect to those of the geographical and temporal weighted regression (GTWR) model for the three simulation datasets. Moreover, compared to the MGWR and GTWR models, the MGTWR model obtained the lowest AIC value and mean square error (MSE) and the highest coefficient of determination (R2) and adjusted coefficient of determination (R2adj). In addition, our experiments proved the existence of both global stationarity and spatiotemporal non-stationarity, as well as the practical ability of the proposed method.
Jiping Liu; Yangyang Zhao; Yi Yang; Shenghua Xu; Fuhao Zhang; Xiaolu Zhang; Lihong Shi; Agen Qiu. A Mixed Geographically and Temporally Weighted Regression: Exploring Spatial-Temporal Variations from Global and Local Perspectives. Entropy 2017, 19, 53 .
AMA StyleJiping Liu, Yangyang Zhao, Yi Yang, Shenghua Xu, Fuhao Zhang, Xiaolu Zhang, Lihong Shi, Agen Qiu. A Mixed Geographically and Temporally Weighted Regression: Exploring Spatial-Temporal Variations from Global and Local Perspectives. Entropy. 2017; 19 (2):53.
Chicago/Turabian StyleJiping Liu; Yangyang Zhao; Yi Yang; Shenghua Xu; Fuhao Zhang; Xiaolu Zhang; Lihong Shi; Agen Qiu. 2017. "A Mixed Geographically and Temporally Weighted Regression: Exploring Spatial-Temporal Variations from Global and Local Perspectives." Entropy 19, no. 2: 53.
Previous studies have demonstrated that non-Euclidean distance metrics can improve model fit in the geographically weighted regression (GWR) model. However, the GWR model often considers spatial nonstationarity and does not address variations in local temporal issues. Therefore, this paper explores a geographically temporal weighted regression (GTWR) approach that accounts for both spatial and temporal nonstationarity simultaneously to estimate house prices based on travel time distance metrics. Using house price data collected between 1980 and 2016, the house price response and explanatory variables are then modeled using both the GWR and the GTWR approaches. Comparing the GWR model with Euclidean and travel distance metrics, the GTWR model with travel distance obtains the highest value for the coefficient of determination (R2) and the lowest values for the Akaike information criterion (AIC). The results show that the GTWR model provides a relatively high goodness of fit and sufficient space-time explanatory power with non-Euclidean distance metrics. The results of this study can be used to formulate more effective policies for real estate management.
Jiping Liu; Yi Yang; Shenghua Xu; Yangyang Zhao; Yong Wang; Fuhao Zhang. A Geographically Temporal Weighted Regression Approach with Travel Distance for House Price Estimation. Entropy 2016, 18, 303 .
AMA StyleJiping Liu, Yi Yang, Shenghua Xu, Yangyang Zhao, Yong Wang, Fuhao Zhang. A Geographically Temporal Weighted Regression Approach with Travel Distance for House Price Estimation. Entropy. 2016; 18 (8):303.
Chicago/Turabian StyleJiping Liu; Yi Yang; Shenghua Xu; Yangyang Zhao; Yong Wang; Fuhao Zhang. 2016. "A Geographically Temporal Weighted Regression Approach with Travel Distance for House Price Estimation." Entropy 18, no. 8: 303.
This paper proposes an extended semi-supervised regression approach to enhance the prediction accuracy of housing prices within the geographical information science field. The method, referred to as co-training geographical weighted regression (COGWR), aims to fully utilize the positive aspects of both the geographical weighted regression (GWR) method and the semi-supervised learning paradigm. Housing prices in Beijing are assessed to validate the feasibility of the proposed model. The COGWR model demonstrated a better goodness-of-fit than the GWR when housing price data were limited because a COGWR is able to effectively absorb no-price data with explanatory variables into its learning by considering spatial variations and nonstationarity that may introduce significant biases into housing prices. This result demonstrates that a semisupervised geographic weighted regression may be effectively used to predict housing prices.
Yi Yang; Jiping Liu; Shenghua Xu; Yangyang Zhao. An Extended Semi-Supervised Regression Approach with Co-Training and Geographical Weighted Regression: A Case Study of Housing Prices in Beijing. ISPRS International Journal of Geo-Information 2016, 5, 4 .
AMA StyleYi Yang, Jiping Liu, Shenghua Xu, Yangyang Zhao. An Extended Semi-Supervised Regression Approach with Co-Training and Geographical Weighted Regression: A Case Study of Housing Prices in Beijing. ISPRS International Journal of Geo-Information. 2016; 5 (1):4.
Chicago/Turabian StyleYi Yang; Jiping Liu; Shenghua Xu; Yangyang Zhao. 2016. "An Extended Semi-Supervised Regression Approach with Co-Training and Geographical Weighted Regression: A Case Study of Housing Prices in Beijing." ISPRS International Journal of Geo-Information 5, no. 1: 4.