顾及空间多尺度邻域效应和时间依赖性的城市扩展模拟

在推进新型城镇化和实施新时代国土空间规划的战略背景下,城市扩展研究逐渐成为热点问题。当前基于元胞自动机(CA)的城市扩展模拟对城市空间多尺度邻域效应解析不足,且在转换规则中对城市长时间演变过程的时间依赖性影响表达不够完善,简化了城市扩展的时空依赖性,无法真实模拟推演未来规划实施情景以服务于国土空间规划。针对上述问题,本文构建一种兼顾空间多尺度邻域效应(3DCNN)和时间依赖性(ConvLSTM)的城市扩展深度学习CA模型(下文称“Deep-CA”)。首先通过组合普通卷积和空洞卷积的3DCNN来提取城市空间多尺度邻域效应,再利用ConvLSTM神经网络将历史信息同化,考虑长时间序列的时间依赖性,从而得到城市扩展的适宜性概率。北京市1995—2015年的土地利用数据及其驱动因素数据用于验证所提CA模型的科学性与适用性,1995—2010年数据用于模型训练,模拟2015年的城市范围。同时将模拟结果精度与ANN-CA、LR-CA和ME-CA 3种传统方法进行对比。与传统CA模型相比,Deep-CA的北京市2015年模拟FoM指数提高了4%左右,且对于城市全局和局部形态模拟效果较好,斑块破碎度低...     

城市扩展极限学习机模型

城市空间结构及其扩展的模拟是城市科学管理与规划的重要前提,本文基于极限学习机提出了顾及不同非城市用地转化为城市用地差异与强度的城市扩展元胞自动机模型（ELM-CA）。模型验证表明：①ELM-CA模型的模拟精度达到70.30%,相比于逻辑回归和神经网络分别提高了2.21%和1.54%,FoM系数分别提高了0.025 9和0.017 9,Kappa系数分别提高了0.024 7和0.016 9,且Moran I指数接近于实际值,说明极限学习机模型较逻辑回归和神经网络能更有效模拟城市扩展的空间形态及其变化;②ELM模型的训练时间仅为神经网络的1/3左右,体现了ELM学习速度的优势;③在小样本情况下,逻辑回归和神经网络都受到明显的影响,而极限学习机还能保持良好的性能,这个特点使其在样本难以获取的情况下具有明显的优势。两个时相的城市扩展模拟与真实数据的比较表明：基于极限学习机的城市扩展元胞自动机模型（ELM-CA）,简化了CA模型的复杂度,并在小样本情况下能有效提高模拟精度,适合于复杂土地利用条件下城市扩展模拟与预测。     

基于元胞自动机的遗传神经网络在土地利用变化模拟分析中的应用

元胞自动机模型在土地扩展的转换规则设计上具有随机性,受周围环境影响较大。文中建立基于BP神经网络和遗传神经网络算法优化的元胞自动机土地扩张模型,对广州市2009—2011年进行城市扩张模拟分析。实验结果显示:BP神经网络能够较好地模拟分布较集中的耕地和林地等区域,精度可达到70%以上,而对于面积较零碎的建筑用地区域,模拟效果较差;而遗传神经网络优化算法能够总体提高模拟精度约5%,部分精度能提高至20%。同时,该算法还能充分考虑影响土地变化的各种扰动因素,优化选择驱动因子和缩短迭代次数,对于城市土地扩张研究具有可行性。     

顾及空间交互作用的城市群联动空间增长模拟——以武汉都市区为例

随着区域城市化与城市区域化的发展,城市群成为中国城市化进程中最引人注目的地区,研究城市群联动空间增长动态也成为了当前研究热点。在城市扩张的研究中,传统以元胞自动机(cellular automaton,CA)为代表的城市扩张模拟方法主要针对单一的城市展开,缺乏对城市群空间交互作用和联动增长效应的建模,难以真实反映城市群的空间扩张过程。通过引入城市流模型来量化城市之间的空间交互作用,并将其作为转换规则嵌入CA模型,构建了一种顾及空间交互作用的城市群联合空间增长扩张过程分析模型,并以武汉都市区为例,模拟了武汉都市区(1个主城区+6个远郊区)的城市扩张过程。与传统的Logistic回归CA模型对比,结果表明,模型模拟精度更高,可以在一定程度上反映城市发展,尤其是城市群联动增长扩张的特征和规律。     

耦合遥感观测和元胞自动机的城市扩张模拟

在传统元胞自动机(CA)模型中,静态的模型参数和模型误差不能释放是影响城市扩张模拟效果的两个重要原因。文中引入集合卡尔曼滤波方法到CA模型中,提出了基于联合状态矩阵的地理元胞自动机。该模型在模拟过程中可以通过同化遥感观测数据,动态地调整模型参数和纠正模拟结果,使模型参数能够反映转换规则的时空变化,同时也能较好地释放积累的模型误差。将模型应用于东莞市的城市扩张模拟中,实验结果表明,模型能够准确地调整模型参数使之符合城市发展模式,同时也能有效地控制模型误差,其模拟的空间格局与真实情况吻合。     

基于CA模型的西安城市空间扩展模拟及误差分析

元胞自动机(CA)是城市发展动态模拟的重要工具。本文以西安市为例,利用基于遗传算法的CA模型对西安市1990-2007年的城市发展进行模拟,得到了较好的效果。结果表明,运用遗传算法建立的CA模型能够较好地模拟城市发展状态;对模拟误差分析表明,影响城市土地利用变化机制的尺度特征,城市规划调整、重大事件、重大建设项目和行政区划调整等过程,城市不同发展阶段和不同区位的扩展类型等都将影响确定转换规则、寻找最佳参数和模拟精度的结果。     

基于粒子群算法的矢量元胞自动机转换规则获取

本文提出了一种基于粒子群算法来自动获取矢量元胞自动机转换规则的新方法。采用粒子群算法所提取的转换规则毋需通过数学公式来表达,能更方便和准确地描述自然界中的复杂关系,并且这些规则比数学公式更容易让人理解。以丹阳市城市扩展为例,使用粒子群算法挖掘元胞自动机转换规则模拟该研究区域的城市扩展过程,并对模拟结果进行了精度评价。     

基于神经网络的元胞自动机与土地利用演化模拟——以广州市白云区为例

城市发展过程中存在多种土地利用类型的相互转换,掌握其演化规律有助于制定出合理的土地利用规划。传统元胞自动机(CA)在模拟城市扩张过程时,多种土地利用类型间的转换十分复杂,往往难以获得转换规则。本文利用神经网络构建了多类型演化的CA模型;从城市演化的历史数据中进行学习,挖掘出控制土地利用方式转变的空间要素权重,利用广州市白云区2005—2007年间的土地利用历史演化数据训练神经网络后,对2009年研究区的土地利用结构进行了模拟。对比同期的真实土地利用格局,模拟结果的平均精度达到77.65%。     

GeoSOS在城市扩展中的应用

城市扩展是一个复杂的时空转换过程,元胞自动机(CA)是一种时空离散、状态简洁,利用简单的局部规则来模拟复杂系统时空演化过程的格网动力模型,CA在城市增长、扩展和土地利用演化的模拟等方面有着巨大的优势。本文基于Geo SOS for Arc GIS平台,分别利用Logistic-CA、ANN-CA和DT-CA这3种模型对长春市主城区1995—2005年、2005—2015年的城市扩展情况进行了模拟,结果表明Logistic-CA、DT-CA两种模型更适用于研究单一土地利用类型的模拟,ANN-CA更适用于涉及多种土地利用类型转换的模拟。而后,利用综合表现最佳的DT-CA模型对长春市主城区2015—2025年的城市扩展进行预测,模拟结果可为相关部门对土地规划的宏观决策提供一定的参考和数据支持。     

MonoLoop:CA城市模型状态转换规则获取的一种方法

状态转换规则是元胞自动机(Cellular Automata,CA)的核心,如何获取并建立CA的状态转换规则是构建CA模型的关键。邻域作用是CA能够模拟复杂物理现象的核心驱动力,而在已有的用于城市增长模拟的CA城市模型中,因为邻域作用在模拟的过程中为时间动态的变量,其系数很难通过常用的Logistic回归方法识别,致使已有的CA城市模型的状态转换规则中,往往仅通过Logistic回归获取邻域作用之外的空间变量的模型参数,而邻域作用的参数通常采用主观赋值的方法。本文提出了CA城市模型的多指标评价(Multi-Criteria Evalua-tion,MCE)形式状态转换规则获取的一种新方法 MonoLoop,并针对北京市域1976～2006年的城市增长开展了该方法的实验。基于这种方法,一方面利用历史数据可以建立更为客观的状态转换规则;另一方面也可以大大降低模型参数识别的时间。     

土地利用变化研究中的细胞自动机与灰色局势决策

把细胞自动机和灰色局势决策结合起来对土地利用变换机制进行模拟。实验证明,基于灰色局势决策规则的细胞自动机是对土地利用变换机制从宏观和微观角度进行模拟的有效方法。     

Simulating urban growth processes by integrating cellular automata model and artificial optimization in Binhai New Area of Tianjin,China

This study presents an optimized algorithm into the cellular automata (CA) models for urban growth simulation in Binhai New Area of Tianjin, China. The optimized CA model by particle swarm optimization (PSO) was compared with the logistic-based cellular automata (LOGIT-CA) model to see the effects of the simulation. The study evaluated the stochastic disturbance in the development of urban growth using the Monte Carlo method; the coefficient d determined the state of urban growth. The validation was conducted by both cross-tabulation test and structural measurements. The results showed that the simulations of PSO-CA were better than LOGIT-CA model, indicating an improvement in the spatio-temporal simulation of urban growth and land use changes in study area. Since the simulations reached their best values when the coefficient was between 1 and 2, the urban growth in the study area was in the period of conversion from spontaneous growth to edge-expansion and infilling growth.     

Simulation of landscape spatial layout evolution in rural-urban fringe areas: a case study of Ganjingzi District

In recent years, the rapid expansion of urban spaces has accelerated the mutual evolution of landscape types. Analyzing and simulating spatio-temporal dynamic features of urban landscape can help to reveal its driving mechanisms and facilitate reasonable planning of urban land resources. The purpose of this study was to design a hybrid cellular automata model to simulate dynamic change in urban landscapes. The model consists of four parts: a geospatial partition, a Markov chain (MC), a multi-layer perceptron artificial neural network (MLP-ANN), and cellular automata (CA). This study employed multivariate land use data for the period 2000–2015 to conduct spatial clustering for the Ganjingzi District and to simulate landscape status evolution via a divisional composite cellular automaton model. During the period of 2000–2015, construction land and forest land areas in Ganjingzi District increased by 19.43% and 15.19%, respectively, whereas farmland, garden lands, and other land areas decreased by 43.42%, 52.14%, and 75.97%, respectively. Land use conversion potentials in different sub-regions show different characteristics in space. The overall land-change prediction accuracy for the subarea-composite model is 3% higher than that of the non-partitioned model, and misses are reduced by 3.1%. Therefore, by integrating geospatial zoning and the MLP-ANN hybrid method, the land type conversion rules of different zonings can be obtained, allowing for more effective simulations of future urban land use change. The hybrid cellular automata model developed here will provide a reference for urban planning and policy formulation.     

Integrating cellular automata,artificial neural network,and fuzzy set theory to simulate threatened orchards: application to Maragheh,Iran

Urbanization processes challenge the growth of orchards in many cities in Iran. In Maragheh, orchards are crucial ecological, economical, and tourist sources. To explore orchards threatened by urban expansion, this study first aims to develop a new model by coupling cellular automata (CA) and artificial neural network with fuzzy set theory (CA–ANN–Fuzzy). While fuzzy set theory captures the uncertainty associated with transition rules, the ANN considers spatial and temporal nonlinearities of the driving forces underlying the urban growth processes. Second, the CA–ANN–Fuzzy model is compared with two existing approaches, namely a basic CA and a CA coupled with an ANN (CA–ANN). Third, we quantify the amount of orchard loss during the last three decades as well as for the upcoming years up to 2025. Results show that CA–ANN–Fuzzy with 83% kappa coefficient performs significantly better than conventional CA (with 51% kappa coefficient) and CA–ANN (with 79% kappa coefficient) models in simulating orchard loss. The historical data shows a considerable loss of 26% during the last three decades, while the CA–ANN–Fuzzy simulation reveals a considerable future loss of 7% of Maragheh’s orchards in 2025 due to urbanization. These areas require special attention and must be protected by the local government and decision-makers.     

An Artificial-Neural-Network-based,Constrained CA Model for Simulating Urban Growth

Insufficient research has been done on integrating artificial-neural-network-based cellular automata (CA) models and constrained CA models, even though both types have been studied for several years. In this paper, a constrained CA model based on an artificial neural network (ANN) was developed to simulate and forecast urban growth. Neural networks can learn from available urban land-use geospatial data and thus deal with redundancy, inaccuracy, and noise during the CA parameter calibration. In the ANN-Urban-CA model we used, a two-layer Back-Propagation (BP) neural network has been integrated into a CA model to seek suitable parameter values that match the historical data. Each cell's probability of urban transformation is determined by the neural network during simulation. A macro-scale socio-economic model was run together with the CA model to estimate demand for urban space in each period in the future. The total number of new urban cells generated by the CA model was constrained, taking such exogenous demands as population forecasts into account. Beijing urban growth between 1980 and 2000 was simulated using this model, and long-term (2001–2015) growth was forecast based on multiple socio-economic scenarios. The ANN-Urban-CA model was found capable of simulating and forecasting the complex and non-linear spatial-temporal process of urban growth in a reasonably short time, with less subjective uncertainty.     

用于沿海城市扩展模拟的一种CA模型

对传统的克拉克城市扩展模型进行了分析,构造了一种适合沿海城市扩展的CA模型.利用建立的CA模型,对沿海城市青岛市的城市扩展进行了模拟,试验结果表明,模型对沿海城市的扩展具有很好的模拟效果.     

Assessing the effect of temporal dynamics on urban growth simulation: Towards an asynchronous cellular automata

Time is a fundamental dimension in urban dynamics, but the effect of various definitions of time on urban growth models has rarely been evaluated. In urban growth models such as cellular automata (CA), time has typically been defined as a sequence of discrete time steps. However, most urban growth processes such as land‐use changes are asynchronous. The aim of this study is to examine the effect of various temporal dynamics scenarios on urban growth simulation, in terms of urban land‐use planning, and to introduce an asynchronous parcel‐based cellular automata (AParCA) model. In this study, eight different scenarios were generated to investigate the impact of temporal dynamics on CA‐based urban growth models, and their outputs were evaluated using various urban planning indicators. The obtained results show that different degrees of temporal dynamics lead to various patterns appearing in urban growth CA models, and the application of asynchronous (event‐driven) CA models achieves better simulation results than synchronous models.     

Integration of neural networks and cellular automata for urban planning

This paper presents a new type of cellular automata (CA) model for the simulation of alternative land development using neural networks for urban planning. CA models can be regarded as a planning tool because they can generate alternative urban growth. Alternative development patterns can be formed by using different sets of parameter values in CA simulation. A critical issue is how to define parameter values for realistic and idealized simulation. This paper demonstrates that neural networks can simplify CA models but generate more plausible results. The simulation is based on a simple three-layer network with an output neuron to generate conversion probability. No transition rules are required for the simulation. Parameter values are automatically obtained from the training of network by using satellite remote sensing data. Original training data can be assessed and modified according to planning objectives. Alternative urban patterns can be easily formulated by using the modified training data sets rather than changing the model.