Your search keyword '"Kaihua Hou"' showing total 8 results

1. Comparing the Accuracy of Peripapillary OCT Scans and Visual Fields to Detect Glaucoma Worsening

Author

Chris Bradley, Patrick Herbert, Kaihua Hou, Mathias Unberath, Pradeep Ramulu, and Jithin Yohannan

Subjects

Ophthalmology

Published

2023

2. Evidence-Based Guidelines for the Number of Peripapillary OCT Scans Needed to Detect Glaucoma Worsening

Author

Chris Bradley, Kaihua Hou, Patrick Herbert, Mathias Unberath, Michael V. Boland, Pradeep Ramulu, and Jithin Yohannan

Subjects

Adult, Retinal Ganglion Cells, Ophthalmology, Nerve Fibers, Optic Disk, Optic Nerve Diseases, Humans, Glaucoma, Ocular Hypertension, Visual Fields, Tomography, Optical Coherence, Intraocular Pressure

Abstract

To estimate the number of OCT scans necessary to detect moderate and rapid rates of retinal nerve fiber layer (RNFL) thickness worsening at different levels of accuracy using a large sample of glaucoma and glaucoma-suspect eyes.Descriptive and simulation study.Twelve thousand one hundred fifty eyes from 7392 adult patients with glaucoma or glaucoma-suspect status followed up at the Wilmer Eye Institute from 2013 through 2021. All eyes had at least 5 measurements of RNFL thickness on the Cirrus OCT (Carl Zeiss Meditec) with signal strength of 6 or more.Rates of RNFL worsening for average RNFL thickness and for the 4 quadrants were measured using linear regression. Simulations were used to estimate the accuracy of detecting worsening-defined as the percentage of patients in whom the true rate of RNFL worsening was at or less than different criterion rates of worsening when the OCT-measured rate was also at or less than these criterion rates-for two different measurement strategies: evenly spaced (equal time intervals between measurements) and clustered (approximately half the measurements at each end point of the period).The 75th percentile (moderate) and 90th percentile (rapid) rates of RNFL worsening for average RNFL thickness and the accuracy of diagnosing worsening at these moderate and rapid rates.The 75th and 90th percentile rates of worsening for average RNFL thickness were -1.09 μm/year and -2.35 μm/year, respectively. Simulations showed that, for the average measurement frequency in our sample of approximately 3 OCT scans over a 2-year period, moderate and rapid RNFL worsening were diagnosed accurately only 47% and 40% of the time, respectively. Estimates for the number of OCT scans needed to achieve a range of accuracy levels are provided. For example, 60% accuracy requires 7 measurements to detect both moderate and rapid worsening within a 2-year period if the more efficient clustered measurement strategy is used.To diagnose RNFL worsening more accurately, the number of OCT scans must be increased compared with current clinical practice. A clustered measurement strategy reduces the number of scans required compared with evenly spacing measurements.

Published

2023

3. Forecasting Risk of Future Rapid Glaucoma Worsening Using Early Visual Field, OCT, and Clinical Data

Author

Patrick Herbert, Kaihua Hou, Chris Bradley, Greg Hager, Michael V. Boland, Pradeep Ramulu, Mathias Unberath, and Jithin Yohannan

Subjects

General Medicine

Published

2023

4. Predicting Visual Field Worsening with Longitudinal OCT Data Using a Gated Transformer Network

Author

Kaihua Hou, Chris Bradley, Patrick Herbert, Chris Johnson, Michael Wall, Pradeep Y. Ramulu, Mathias Unberath, and Jithin Yohannan

Subjects

Ophthalmology

Published

2023

5. STGI：a spatio-temporal grid index model for marine big data

Author

Jining Yan, Jian Yu, Meng Li, Chengqi Cheng, Tengteng Qu, Kaihua Hou, Bo Chen, Guilin Xu, and Lizhe Wang

Subjects

marine big data, Index (economics), business.industry, Computer science, Data management, Big data, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, spatio-temporal grid index model, mongodb, Grid, computer.software_genre, geosot, Computer Science Applications, lcsh:Geology, lcsh:G, Grid code, Data mining, Computers in Earth Sciences, Composite index, business, computer

Abstract

Marine big data are characterized by a large amount and complex structures, which bring great challenges to data management and retrieval. Based on the GeoSOT Grid Code and the composite index structure of the MongoDB database, this paper proposes a spatio-temporal grid index model (STGI) for efficient optimized query of marine big data. A spatio-temporal secondary index is created on the spatial code and time code columns to build a composite index in the MongoDB database used for the storage of massive marine data. Multiple comparative experiments demonstrate that the retrieval efficiency adopting the STGI approach is increased by more than two to three times compared with other index models. Through theoretical analysis and experimental verification, the conclusion could be achieved that the STGI model is quite suitable for retrieving large-scale spatial data with low time frequency, such as marine big data.

Published

2020

6. A Set of Integral Grid-Coding Algebraic Operations Based on GeoSOT-3D

Author

Chengqi Cheng, Bo Chen, Li Meng, Shuang Li, Chi Zhang, Kaihua Hou, and Liesong He

Subjects

algebraic operation framework, Geospatial analysis, 010504 meteorology & atmospheric sciences, Relation (database), Computer science, Geography, Planning and Development, 0211 other engineering and technologies, 02 engineering and technology, computer.software_genre, 01 natural sciences, Set (abstract data type), GeoSOT-3D, Earth and Planetary Sciences (miscellaneous), Set operations, grid code, Computers in Earth Sciences, Spatial analysis, real-time processing, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Geography (General), Grid, big geospatial data, Computer engineering, Algebraic operation, Grid code, G1-922, computer

Abstract

As the amount of collected spatial information (2D/3D) increases, the real-time processing of these massive data is among the urgent issues that need to be dealt with. Discretizing the physical earth into a digital gridded earth and assigning an integral computable code to each grid has become an effective way to accelerate real-time processing. Researchers have proposed optimization algorithms for spatial calculations in specific scenarios. However, a complete set of algorithms for real-time processing using grid coding is still lacking. To address this issue, a carefully designed, integral grid-coding algebraic operation framework for GeoSOT-3D (a multilayer latitude and longitude grid model) is proposed. By converting traditional floating-point calculations based on latitude and longitude into binary operations, the complexity of the algorithm is greatly reduced. We then present the detailed algorithms that were designed, including basic operations, vector operations, code conversion operations, spatial operations, metric operations, topological relation operations, and set operations. To verify the feasibility and efficiency of the above algorithms, we developed an experimental platform using C++ language (including major algorithms, and more algorithms may be expanded in the future). Then, we generated random data and conducted experiments. The experimental results show that the computing framework is feasible and can significantly improve the efficiency of spatial processing. The algebraic operation framework is expected to support large geospatial data retrieval and analysis, and experience a revival, on top of parallel and distributed computing, in an era of large geospatial data.

Published

2021

7. A Universal Generating Algorithm of the Polyhedral Discrete Grid Based on Unit Duplication

Author

Kaihua Hou, Shuaibo Fan, Li Meng, Chengqi Cheng, Weiming Yang, Bo Chen, and Xiaochong Tong

Subjects

Computer science, Icosahedral symmetry, hexagonal grid, Geography, Planning and Development, Coordinate system, unit replication, 0211 other engineering and technologies, 0507 social and economic geography, lcsh:G1-922, 02 engineering and technology, law.invention, regular icosahedron, law, regional control, Earth and Planetary Sciences (miscellaneous), Cartesian coordinate system, Computers in Earth Sciences, Scaling, Computer Science::Distributed, Parallel, and Cluster Computing, ComputingMethodologies_COMPUTERGRAPHICS, 021101 geological & geomatics engineering, Subdivision, Hexagonal tiling, discrete global grid system, business.industry, 05 social sciences, Grid, Quantitative Biology::Genomics, Computer Science::Computers and Society, business, Geographic coordinate system, 050703 geography, Algorithm, lcsh:Geography (General)

Abstract

Based on the analysis of the problems in the generation algorithm of discrete grid systems domestically and abroad, a new universal algorithm for the unit duplication of a polyhedral discrete grid is proposed, and its core is &ldquo, simple unit replication + effective region restriction&rdquo, First, the grid coordinate system and the corresponding spatial rectangular coordinate system are established to determine the rectangular coordinates of any grid cell node. Then, the type of the subdivision grid system to be calculated is determined to identify the three key factors affecting the grid types, which are the position of the starting point, the length of the starting edge, and the direction of the starting edge. On this basis, the effective boundary of a multiscale grid can be determined and the grid coordinates of a multiscale grid can be obtained. A one-to-one correspondence between the multiscale grids and subdivision types can be established. Through the appropriate rotation, translation and scaling of the multiscale grid, the node coordinates of a single triangular grid system are calculated, and the relationships between the nodes of different levels are established. Finally, this paper takes a hexagonal grid as an example to carry out the experiment verifications by converting a single triangular grid system (plane) directly to a single triangular grid with a positive icosahedral surface to generate a positive icosahedral surface grid. The experimental results show that the algorithm has good universality and can generate the multiscale grid of an arbitrary grid configuration by adjusting the corresponding starting transformation parameters.

Published

2019

8. A Space-Interconnection Algorithm for Satellite Constellation Based on Spatial Grid Model

Author

Shuang Li, Chengqi Cheng, Bo Chen, Shizhong Li, and Kaihua Hou

Subjects

010504 meteorology & atmospheric sciences, Computer science, Science, Node (networking), Visibility (geometry), 0211 other engineering and technologies, Satellite constellation, BigTable, 02 engineering and technology, Grid, 01 natural sciences, satellite communication, satellite visibility, GeoSOT-3D, Physics::Space Physics, route planning, Communications satellite, General Earth and Planetary Sciences, Satellite, Satellite Internet access, Motion planning, Algorithm, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

With the rapid development of large-scale satellite constellations and the increasing demand for rapid communication and emergency rescue using global satellite-based Internet, there have been new requirements for efficient algorithms for inter-communication between satellites. As the constellations of low-orbit satellites become larger, the complexities of real-time inter-satellite calculation and path planning are becoming more complicated and are increasing geometrically. To address the bottlenecks in large-scale node space computing, we introduced a global space grid. Based on this grid, an efficient calculation method of spatial inter-connection between satellite constellations is proposed, according to the concept of “storage for computing” and the high computational efficiency of the spatial grid model. This strategy includes the following parts: (1) the introduction of the GeoSOT-3D global grid model into aerospace and the construction of the aerospace grid indexing BigTable; (2) a set of algorithms for satellite visibility analysis according to the visible grid look-up table and the secondary grid index; and (3) planning inter-satellite routing by querying the grid’s inherent visibility. The idea at the basis of this method is to employ the “space for time” concept to convert the high-dimensional floating operations into one-dimensional matching operations by querying the inherent “visible” attribute of the grid. In our study, we simulated thousands of satellites, discretized their trajectories into grids, and pre-calculated the visibility between grid cells to plan the routing path for the ground data transmission. The theoretical analysis and experimental verification show that the algorithm is feasible and efficient, and it can significantly improve the computational efficiency of inter-satellite connection. We hope that the method can be used in emergency communications, disaster warning, and maritime rescue, and can contribute to the next generation of satellite internet and “satellite-ground” integrated networks.

Published

2020