建立工程勘察资料信息系统的设计思想

随着计算机技术的发展和应用的普及，人们对信息的处理和信息的利用提出了更高的要求。信息系统能及时地输出和传递所需的信息。本文简要地探讨了工程勘察资料信息系统的开发思路。     

基于GIS和RDB的勘察数据一体化管理

工程勘察中的原始数据、成果资料中包含着较强的关联关系,有效地利用和表现这些内在关系有利于数据的存储管理和检索使用,因此勘察信息系统不仅要实现数据采集、图件编绘等的计算机辅助化,更要在成果使用管理上发挥计算机技术的优势,以体现勘察成果间的内在联系。在分析及明确了各类资料间固有的联系基础上,建立了基于GIS（地理信息系统）的数据模型和资料生成模式以及基于RDB（关系数据库）技术的勘察资料管理模式。结果证明,基于GIS和RDB的勘察信息系统不仅可以满足基层单位用户的业务需求,而且可以可自动建立成果间的联系,实现勘察数据的一体化管理。     

利用Access97和VB6的ADO开发工程勘察数据库

根据开发工程勘察数据库的经历,介绍了利用YB6的ADO和Access97开发工程勘察数据库的步骤、方法和技巧,以及开发过程中可能遇到的问题和解决办法。     

基于Geoview的地质灾害勘察资料一体化管理

借助地理信息系统技术,分析、明确了各成果资料间固有的联系,建立了基于GIS和RDB技术的勘察资料生成、存储、管理使用模式,并以Geoview为GIS平台开发了地质灾害勘察信息系统--GeoHazard,该系统不仅实现了当前基于CAD的勘察系统的可视化数据采集存储、图件编绘功能,而且实现了地质灾害勘察过程中的文档、图件、属性记录等的一体化关联存储.     

面向勘察与管理的三峡库区地灾勘察点源信息系统

三峡库区地质灾害勘察治理具有工程数量多、数据量浩大、资料上交时间段集中的特点。基层信息软件不仅要满足基层业务需要,还应兼顾后期资料管理和使用需求,为此研发了面向勘察单位和管理部门的勘察点源信息系统GeoHazard。该系统以地矿点源信息系统思想为指导,点源主题数据库为核心,设计了基于地理底图的数据采集、基于GIS的图件编绘、基于图件的可视化查询检索和基于网络的远程数据汇交等工作方案;初步实现勘察工作中数据采集、图形编绘、存储管理、输出的全程计算机辅助化;具有支持地质灾害勘察应用的专业性、面向地质灾害勘察工作全过程的完整性、术语代码和图式图例的标准化、各类数据和资料管理的一体化、数据分析检索和表达的可视化等特点。     

工程活动断裂判据与对策

提要 本文根据我国工程实践，地质条件和作者认识，参考了国外资料，从工程地质观点提出了工程活动断裂的定义和判据，供工程勘察利用和参考。     

市政道路工程勘察资料的时效性分析和探讨

城市化的发展,使市政道路改造工程越来越多,如何科学有效地利用拟建期的勘察资料,节约勘察成本,成为工程勘察关注的焦点。通过对场地地形地貌和地质构造、地层和水文地质条件、岩土物理力学性质、场地稳定性评价和地震效应、岩土工程重点分析评价等岩土工程要素进行分析,对比前后各要素,探讨勘察资料的时效性,进而确定勘察点布置和深度,以及取土（水）样和原位测试工作量。最后以具体工程为例,探讨勘察要点,指出利用拟建期的勘察资料应主要考虑4.0m以内的地层变化,重点勘察路基破损的路段。     

岩土工程勘察土工试验数据自动化处理实现方法

岩土工程勘察工作的内业资料整理过程中，土工试验数据处理是影响勘察报告质量及进度的主要因素之一，本文基于Microsoft EXCEL软件的简单开发，将手工处理土工试验资料的过程程序化、简单化，从而提高土工试验数据处理速度和报告质量。     

工程勘察协作信息系统的研究与实现

在分析勘察企业的实际应用需求的基础上，该系统介绍了基于C／S和B／S模式的工程勘察协作信息系统的系统组成、总体设计以及实现方法。集成了勘察企业生产经营的各个部分，全面实现了信息资源共享，分工协作，同时能够为领导决策提供辅助支持。     

地质信息共享平台发展概述及思考

近几十年来，工程勘察行业发展缓慢。通过引入互联网数字化平台模式，开发工程地质信息共享平台，实现了勘察成果的有效利用，推动了岩土工程经验评价体系发展，增强了行业的活力和效益。文章系统回顾了国内外地质信息共享平台和相关标准的发展情况，总结了平台开发的意义和目前面临的问题和挑战，针对全要素地质信息平台的建设建议如下：（1）加强全要素地质信息共建共享机制探索；（2）引入欧美国家广泛应用的AGS格式，进行数据存储和传输标准开发；（3）解放工程勘察行业长期以来的保守和封闭思想；（4）引入风投资本有效保障平台持续开发的资本投入。     

洞穴石笋地质事件的定年及意义

本文以贵州荔波董歌洞3号石笋第6、1次和4号石笋第2次主要沉积间断为例,说明依序发生于89.96kaBP、128.65kaBP、113.40kaBP,结束于0.32kaBP、128.21kaBP、65.50kaBP,延续时间89.65ka、0.44ka、47.90ka的沉积间断,具多级次的地质、气候演变属性,沉积间断时间长,显示度明显,气候事件复杂,间断频发,必有更丰富的气候、环境、地质内涵。贵州都匀凯酉七星洞2号石笋Q2F1、Q2F2,5号石笋Q5F3是碰断面,依序发生于74.24kaBP、60.72kaBP、36.80kaBP,彼此相间隔13.52ka、23.92ka,断面及其上、下石笋段的沉积特征,属突变(灾害)性事件,也有其古气候环境意义。系列事件的测年,须在系统测年基础上,于间断、碰断面上下加密测试,及石笋沉积特征的综合观测,以提高事件测年和定性的可信度,增加古气候环境信息量。     

Modeling of Beams on Reinforced Granular Beds

The paper describes a mechanical model for estimating the flexural response of a strip footing, supporting a column (imposing a concentrated load), resting on a compacted granular bed overlying a reinforcement layer for example, geogrids, geomats etc. below which lies a loose soil deposit. The footing is idealized as a beam and the reinforcing element is assumed to have finite bending stiffness and negligible frictional resistance. The upper and lower soil layers are idealized by a series of linear and discrete springs (Winkler springs) of different stiffness values. To find the response of such a model the governing differential equations have been derived and expressed in a nondimensional form. A closed form analytical solution of the same has been obtained subjected to appropriate boundary conditions. Using the present approach the resulting solution for a degenerated case of a long beam is found to be identical to the same of Hetenyi (1946, Beams on elastic foundations, University of Michigan press, Ann Arbor, MI). Parametric studies reveal that the ratio of flexural rigidity of upper and lower beam and the ratio of stiffness of the upper and lower soil layers affect significantly the response of the foundation.     

博斯腾湖碳酸盐和同位素组成的全新世古环境演变高分辨记录及与冰川活动的响应

本文通过对在新疆南部塔里木盆地北缘博斯腾湖采集的一根953cm的岩心进行了早全新世以来的古气候重建。对BSTC2000岩心进行了碳酸盐矿物组成、Ca/1000Sr,有机质TOC,C/N和C/S分析,并结合BSTC2000岩心附近的一个沉积物剖面的孢粉资料,利用多指标重建了8500aBP以来的古气候变化特征。在2个平行岩心中对保存的植物叶片、草籽,以及全有机质进行了9个AMS14C年代测定。8500～8100aBP气候冷湿,钻孔位置为河流-滨湖相环境,沉积物中有3层泥炭层。从8100～6400aBP,气温升高,湖泊扩张,气候暖湿,湖泊可能为最高湖面时期。而从6400～5100aBP湖泊稍微下降,气候变冷。在中全新世晚期从5100～3100aBP气候变得高温干旱,但其间的4400～3800aBP有短暂的气候变冷,早期大量的冰雪融水补给博斯腾湖,使得湖泊水位上升。湖泊的第二个高湖面期是5200～3800aBP。在3100～2200aBP气候冷湿,由于蒸发减弱而湖泊有所扩张,湖泊在3100至2800aBP期间是最后一次短暂的高湖面期。这次短期高湖面后,湖泊由于较长时期的低温而引起的供水减少,湖泊收缩。从2200～1200aBP,气候变得干热,湖泊收缩。尽管从1200aBP以来,温度有所下降,气候变得暖干,湖泊又开始有所上升,但是没有达到博斯腾湖出水口孔雀河的海拔高度。     

Analyzing empowerment: An ongoing process of building state-civil society relations - The case of Walnut Way in Milwaukee

Arguments regarding citizen involvement and empowerment within neoliberal urban politics are ample in geographic literature. Existing discussions often define and evaluate empowerment as either some social, political, or economic end-product of a specific event. Such singular conceptualization is problematic. First, different kinds of social, political, and economic changes can simultaneously empower/disempower communities in contradictory ways. In addition, the view of empowerment as an end-product of a present event obscures a more nuanced understanding of empowerment as an ongoing process of state-civil society relation-building. An in-depth assessment of such a process is only possible with reference to the past and the potential future occurrences. Elwood’s (2002) multi-dimensional conceptualization of empowerment recognizes the limitations of a singular definition of empowerment. However, it falls short of operationalizing empowerment as a temporal process with a historically and geographically contingent past, dynamic present, and future in the making. Therefore, in this paper I expand on Elwood’s framework to show how a process-based view as opposed to a narrow end-product-based or event-based one can provide a deeper understanding of state-civil society interaction and community empowerment. This paper analyzes the interaction between the City of Milwaukee, the residents of a predominantly black inner-city neighborhood, the Walnut Way, and their community organization, the Walnut Way Conservation Corp. within a land-use dispute related to the development of a park space into a housing project. Using data collected through semi-structured in-depth interviews, archival research, and participant observation, this paper emphasizes that despite methodological limitations of collecting long-term data, community empowerment can and should be studied as a process with reference to the past, present, and potential future state-civil society interactions.     

太白山佛爷池剖面的全新世环境变化信息

太白山佛爷池海拔3410m,是一个发育在古冰斗中的冰蚀湖。自湖中210cm沉积剖面进行沉积物粒度、孢粉和测年采样分析,表明自8200aBP以来的环境经历了明显的冷暖干湿变化。8200~6800aBP温暖湿润,在7200aBP出现明显增温;6800~5900aBP气候开始波动,大约在6300aBP有一次短暂的变冷,在6000aBP前后出现明显暖期;5900~4800aBP气温下降,大约在5200aBP达到最低,然后气温缓慢回升;4800~2600aBP气候较为温暖湿润,大约在3000aBP达到最高;2600~900aBP气候变冷湿,大约1500aBP达到最低;900aBP~现代变好。      

Impact of climate change on wetland ecosystems: A critical review of experimental wetlands

Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change.     

Impact of climate change on wetland ecosystems: A critical review of experimental wetlands

Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change.     

Impact of climate change on wetland ecosystems: A critical review of experimental wetlands

Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change.     

Impact of climate change on wetland ecosystems: A critical review of experimental wetlands

Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change.     

Putting accessibility in place: A relational reading of accessibility in policies for transit-oriented development

In order to facilitate sustainable development, a shift from mobility-based to accessibility-based planning has been suggested. However, if we rely on the modern conceptualisation of accessibility, such a shift would have limited results. As an alternative, this paper proposes a relational reading of accessibility, which questions the divide between mobility and place upon which the modern definition is based. It argues that the accessibility of a place is characterised by a specific coordination of presences and absences that depends as much on boundaries and exclusions as on mobility. If accessibility changes, so does the place. This interpretation makes accessibility a matter of priorities and provides a critical perspective on arguments for time–space compressions and progress. This is illustrated here using the example of a regional strategy for transit-oriented development in Sweden (Region Scania). For that case, the discourse on accessibility revealed simplified arguments for densification, progress and metropolitan ideals, contradicting the initial inclusive intentions of the strategy. Thus, there is a need to put accessibility in place so that a shift to accessibility-based planning facilitates a move towards social and environmental sustainability.