工程造价专业毕业外文文献、中英对照

建筑造价中英文对照外文翻译文献(文档含英文原文和中文翻译)The Cost of Building Structure1. IntroductionThe art of architectural design was characterized as one of dealing comprehensively with a complex set of physical and nonphysical design determinants. Structural considerations were cast as important physical determinants that should be dealt with in a hierarchical fashion if they are to have a significant impact on spatial organization and environmental control design thinking.The economical aspect of building represents a nonphysical structural consideration that, in final analysis, must also be considered important. Cost considerations are in certain ways a constraint to creative design. But this need not beso. If something is known of the relationship between structural and constructive design options and their cost of implementation, it is reasonable to believe that creativity can be enhanced. This has been confirmed by the authors’ observation that most enhanced. This has been confirmed by the authors’observation that most creative design innovations succeed under competitive bidding and not because of unusual owner affluence as the few publicized cases of extravagance might lead one to believe. One could even say that a designer who is truly creative will produce architectural excellence within the constraints of economy. Especially today, we find that there is a need to recognize that elegance and economy can become synonymous concepts.Therefore, in this chapter we will set forth a brief explanation of the parameters of cost analysis and the means by which designers may evaluate the overall economic implications of their structural and architectural design thinking.The cost of structure alone can be measured relative to the total cost of building construction. Or, since the total construction cost is but a part of a total project cost, one could include additional consideration for land(10～20percent),finance and interest(100～200 percent),taxes and maintenance costs (on the order of20 percent).But a discussion of these so-called architectural costs is beyond the scope of this book, and we will focus on the cost of construction only.On the average, purely structural costs account for about 25 percent of total construction costs, This is so because it has been traditional to discriminate between purely structural and other so-called architectural costs of construction. Thus, in tradition we find that architectural costs have been taken to be those that are not necessary for the structural strength and physical integrity of a building design.“Essential services”forms a third construction cost category and refers to the provision of mechanical and electrical equipment and other service systems. On the average, these service costs account for some 15 to 30 percent of the total construction cost, depending on the type of building. Mechanical and electrical refers to the cost of providing for air-conditioning equipment and he means on air distribution as well as other services, such as plumbing, communications, and electrical light and power.The salient point is that this breakdown of costs suggests that, up to now, an average of about 45 to 60 percent of the total cost of constructing a typical design solution could be considered as architectural. But this picture is rapidly changing.With high interest costs and a scarcity of capital, client groups are demanding leaner designs. Therefore, one may conclude that there are two approaches the designer may take towards influencing the construction cost of building.The first approach to cost efficiency is to consider that wherever architectural and structural solutions can be achieved simultaneously, a potential for economy is evident. Since current trends indicate a reluctance to allocate large portions of a construction budget to purely architectural costs, this approach seems a logical necessity. But, even where money is available, any use of structure to play a basic architectural role will allow the nonstructural budget to be applied to fulfill other architectural needs that might normally have to be applied to fulfill other architectural needs that might normally have to be cut back. The second approach achieves economy through an integration of service and structural subsystems to round out one’s effort to produce a total architectural solution to a building design problem.The final pricing of a project by the constructor or contractor usually takes a different form. The costs are broken down into (1) cost of materials brought to the site, (2)cost of labor involved in every phase of the construction process, (3)cost of equipment purchased or rented for the project, (4)cost of management and overhead, and(5) profit. The architect or engineer seldom follows such an accurate path but should perhaps keep in mind how the actual cost of a structure is finally priced and made up.Thus, the percent averages stated above are obviously crude, but they can suffice to introduce the nature of the cost picture. The following sections will discuss the range of these averages and then proceed to a discussion of square footage costs and volume-based estimates for use in rough approximation of the cost of building a structural system.2. Percentage EstimatesThe type of building project may indicate the range of percentages that can be allocated to structural and other costs. As might be expected, highly decorative or symbolic buildings would normally demand the lowest percentage of structural costs as compared to total construction cost. In this case the structural costs might drop to 10～15percent of the total building cost because more money is allocated to the so-called architectural costs. Once again this implies that the symbolic components are conceived independent of basic structural requirements. However, where structure and symbolism are more-or-less synthesized, as with a church or Cathedral, thestructural system cost can be expected to be somewhat higher, say, 15and20 percent (or more).At the other end of the cost scale are the very simple and nonsymbolic industrial buildings, such as warehouses and garages. In these cases, the nonstructural systems, such as interior partition walls and ceilings, as will as mechanical systems, are normally minimal, as is decoration, and therefore the structural costs can account for60 to 70 percent, even 80 percent of the total cost of construction.Buildings such as medium-rise office and apartment buildings(5～10 stories)occupy the median position on a cost scale at about 25 percent for structure. Low and short-span buildings for commerce and housing, say, of three or four stories and with spans of some 20 or 30 ft and simple erection requirements, will yield structural costs of 15～20 percent of total building cost.Special-performance buildings, such as laboratories and hospitals, represent another category. They can require long spans and a more than average portion of the total costs will be allocated to services (i.e., 30～50 percent), with about 20 percent going for the purely structural costs. Tall office building (15 stories or more) and/or long-span buildings (say, 50 to 60 ft) can require a higher percentage for structural costs (about 30to 35percent of the total construction costs),with about 30 to 40 percent allocated to services.In my case, these percentages are typical and can be considered as a measure of average efficiency in design of buildings. For example, if a low, short-span and nonmonumental building were to be bid at 30 percent for the structure alone, one could assume that the structural design may be comparatively uneconomical. On the other hand, the architect should be aware of the confusing fact that economical bids depend on the practical ability of both the designer and the contractor to interpret the design and construction requirements so that a low bid will ensue. Progress in structural design is often limited more by the designer’s or contractor’slack of experience, imagination, and absence of communication than by the idea of the design. If a contractor is uncertain, he will add costs to hedge the risk he will be taking. It is for this reason that both the architect and the engineer should be well-versed in the area of construction potentials if innovative designs ate to be competitively bid. At the least the architect must be capable of working closely with imaginative structural engineers, contractors and even fabricators wherever possible even if the architecture is very ordinary. Efficiency always requires knowledge and above all imagination, andthese are essential when designs are unfamiliar.The foregoing percentages can be helpful in approximating total construction costs if the assumption is made that structural design is at least of average (of typical) efficiency. For example, if a total office building construction cost budget is ﹩5,000,000,and 25 percent is the “standard”to be used for structure, a projected structural system should cost no more than ﹩1,250,000.If a very efficient design were realized, say, at 80 percent of what would be given by the “average” efficient design estimate stated above the savings,(20 percent),would then be﹩250,000 or 5 percent of total construction costs ﹩5,000,000.If the ﹩5,000,000 figure is committed, then the savings of ﹩250,000 could be applied to expand the budget for “other” costs.All this suggests that creative integration of structural (and mechanical and electrical) design with the total architectural design concept can result in either a reduction in purely construction design concept can result in either a reduction in purely construction costs or more architecture for the same cost. Thus, the degree of success possible depends on knowledge, cleverness, and insightful collaboration of the designers and contractors.The above discussion is only meant to give the reader an overall perspective on total construction costs. The following sections will now furnish the means for estimating the cost of structure alone. Two alternative means will be provided for making an approximate structural cost estimate: one on a square foot of building basis, and another on volumes of structural materials used. Such costs can then be used to get a rough idea of total cost by referring to the “standards” for efficient design given above. At best, this will be a crude measure, but it is hoped that the reader will find that it makes him somewhat familiar with the type of real economic problems that responsible designers must deal with. At the least, this capability will be useful in comparing alternative systems for the purpose of determining their relative cost efficiency.3. Square-foot EstimatingAs before, it is possible to empirically determine a “standard” per-square-foot cost factor based on the average of costs for similar construction at a given place and time. more-or-less efficient designs are possible, depending on the ability of the designer and contractor to use materials and labor efficiently, and vary from the average.The range of square-foot costs for “normal” structural systems is ﹩10 to ﹩16psf. For example, typical office buildings average between ﹩12 and ﹩16 psf, and apartment-type structures range from ﹩10 to ﹩14.In each case, the lower part of the range refers to short spans and low buildings, whereas the upper portion refers to longer spans and moderately tall buildings.Ordinary industrial structures are simple and normally produce square-foot costs ranging from ﹩10 to ﹩14,as with the more typical apartment building. Although the spans for industrial structures are generally longer than those for apartment buildings, and the loads heavier, they commonly have fewer complexities as well as fewer interior walls, partitions, ceiling requirements, and they are not tall. In other words, simplicity of design and erection can offset the additional cost for longer span lengths and heavier loads in industrial buildings.Of course there are exceptions to these averages. The limits of variation depend on a system’s complexity, span length over “normal” and special loading or foundation conditions. For example, the Crown Zellerbach high-rise bank and office building in San Francisco is an exception, since its structural costs were unusually high. However, in this case, the use of 60 ft steel spans and free-standing columns at the bottom, which carry the considerable earthquake loading, as well as the special foundation associated with the poor San Francisco soil conditions, contributed to the exceptionally high costs. The design was also unusual for its time and a decision had been made to allow higher than normal costs for all aspects of the building to achieve open spaces and for both function and symbolic reasons. Hence the proportion of structural to total cost probably remained similar to ordinary buildings.The effect of spans longer than normal can be further illustrated. The “usual” floor span range is as follows: for apartment buildings,16 to 25 ft; for office buildings,20 to 30 ft; for industrial buildings,25 to 30 ft loaded heavily at 200 to 300 psf; and garage-type structures span,50 to 60 ft, carrying relatively light(50～75 psf) loads(i.e., similar to those for apartment and office structures).where these spans are doubled, the structural costs can be expected to rise about 20 to 30 percent.To increased loading in the case of industrial buildings offers another insight into the dependency of cost estimates on “usual” standards. If the loading in an industrial building were to be increased to 500psf(i.e., two or three times), the additional structural cost would be on the order of another 20 to 30 percent.The reference in the above cases is for floor systems. For roofs using efficient orthotropic (flat) systems, contemporary limits for economical design appear to be onthe order of 150 ft, whether of steel or prestressed concrete. Although space- frames are often used for steel or prestressed concrete. Although space-frames are often used for steel spans over 150 ft the fabrication costs begin to raise considerably.At any rate, it should be recognized that very long-span subsystems are special cases and can in themselves have a great or small effect on is added, structural costs for special buildings can vary greatly from design to design. The more special the form, themore that design knowledge and creativity, as well as construction skill, will determine the potential for achieving cost efficiency.4. Volume-Based EstimatesWhen more accuracy is desired, estimates of costs can be based on the volume of materials used to do a job. At first glance it might seem that the architect would be ill equipped to estimate the volume of material required in construction with any accuracy, and much less speed. But it is possible, with a moderate learning effort, to achieve some capability for making such estimates.V olume-based estimates are given by assigning in-place value to the pounds or tons of steel, or the cubic yards of reinforced or prestressed concrete required to build a structural system. For such a preliminary estimate, one does not need to itemize detailed costs. For example, in-place concrete costs include the cost of forming, falsework, reinforcing steel, labor, and overhead. Steel includes fabrication and erection of components.Costs of structural steel as measured by weight range from ﹩0.50 to ﹩0.70 per pound in place for building construction. For low-rise buildings, one can use stock wide-flange structural members that require minimum fabrication, and the cost could be as bow as ﹩0.50 per pound. More complicated systems requiring much cutting and welding(such as a complicated steel truss or space-frame design) can go to ﹩0.70 per pound and beyond. For standard tall building designs (say, exceeding 20 stories),there would typically be about 20 to 30 pounds of steel/psf, which one should wish not to exceed. A design calling for under 20 psf would require a great deal of ingenuity and the careful integration of structural and architectural components and would be a real accomplishment.Concrete costs are volumetric and should range from an in-place low of ﹩150 per cu yd for very simple reinforced concrete work to ﹩300 per cu yd for expensive small quantity precast and prestressed work. This large range is due to the fact that the contributing variables are more complicated, depending upon the shape of the precisecomponents, the erection problems, and the total quantity produced.Form work is generally the controlling factor for any cast-in-place concrete work. Therefore, to achieve a cost of ﹩150 per cu yd, only the simplest of systems can be used, such as flat slabs that require little cutting and much reuse of forms. Where any beams are introduced that require special forms and difficulty in placement of concrete and steel bars, the range begins at ﹩180 per cu yd and goes up to ﹩300.Since, in a developed country, high labor costs account for high forming costs, this results in pressure to use the simplest and most repetitive of systems to keep costs down. It become rewarding to consider the possibility of mass-produced precast and prestressed components, which may bring a saving in costs and\or construction completion time. The latter results in savings due to lower construction financing costs for the contractor plus quicker earnings for the owner.To summarize, the range of cost per cubic yard of standard types of poured-in-place concrete work will average from $150 to $250, the minimum being for simple reinforced work and the maximum for moderately complicated post tensioned work. This range is large and any estimate that ignores the effect of variables above will be commensurately inaccurate.5.SummaryThe estimate and economical design of structure building are important and essential work, which should be valued by all architects and engineers and others. Better you do it, more profit you will receive from it!建筑结构的成本1.前言众所周知，建筑物的结构设计是一个相当复杂的过程，其中既包含处理很多物质因素，又考虑诸多非物质方面的因素。

Evaluation of the influence of the organizational environment on projectcost management based on the Grey Relational AnalysisZhi Dou,Wenjun YangCollege of Civil Engineering ，Chang'an University ，Xi'an 710061，ChinaKeywords ：the Organizational Environment, Engineering Project, Cost Management, ImpactEvaluation, Grey Relational AnalysisAbstract. From the organizational environment perspective, to explore the influence factors ofproject cost management, and to determine a evaluation system about the influence of theorganizational environment on project cost management. Using gray system theory to build a modelof the gray relational analysis between organizational environment and project cost management.The examples show that this method has a certain theoretical significance and practical value tosolve the project cost management.IntroductionAccompanied by the rapid development of China's construction industry and the further openingup of construction markets, the uncertainty of the external environment which constructionenterprises face increased, the underpricing bid between enterprises for contending projects, thedrastic fluctuation in raw material prices, the entering barriers are down while the exit cost are stillhigh, the ferocious entering momentum of foreign builders, these make China constructionenterprises stand in a competitive industry, and its profit margins are severely squeezed. The way toeffectively control the project cost has already become a focus of attention of constructionenterprises. Survey shows that the extensive management approach of China's constructionenterprises currently has not been fundamentally changed, the corporate structure, operationalprocesses and infrastructure management is weak, the level of project management is low, and theexisting project cost should be improved in aspects about management concepts, objectives, meansand so on [1].The effective implementation of advanced cost management methods must considerenterprises' particular organizational environment, Kaplan and Norton believes, the advanced costmanagement and evaluation methods break away from its corresponding organizationalenvironment, the possibility to success almost not exists [2].Therefore, the objective understandingof the organizational environment the construction enterprises face, and the comprehensive analysisabout the mechanism of the organizational environment to the project cost management for theconstruction cost management is essential.The determination of the affecting factor system of the project cost management byorganizational environmentOrganizational environment is a sum of forces and conditions which exist in the internal andexternal organization and affect the organizational performance. There are many environmentalfactors in internal and external organization, but not all of these factors constitute the organization'senvironment, the factors who has no impact on organizational performance do not belong to theenvironmental factors of organization, and elements of the organizational environment is often influx, the dynamics of environment perform clearly in a background of fierce competition both indomestic and foreign markets [3].According to the organization's controllable degree to its faced environment, the organizationalenvironment can be divided into two categories: the internal organizational environment and theexternal organizational environment. The external environment that construction enterprises face isthe sum of various factors which exist around the construction organization and affect the businessactivities and development of enterprises. The external environmental uncertainty of constructionInternational Conference on Education Technology, Management and Humanities Science (ETMHS 2015) © 2015. The authors - Published by Atlantis Press 985enterprises include the general environmental uncertainty and the task environmental uncertainty,the general environmental uncertainty include the uncertainties which brought for constructionenterprises from the political environment, economic environment, legal environment and technicalenvironment, and the task environmental uncertainty include the uncertainties which brought forconstruction enterprises from new entrants, owners, suppliers and existing competitors.Through the above analysis, the several affecting factors of the project cost management by theorganizational environment were researched; this paper considers the factors are: organizationstructure, control system and social relations. And the table 1, the affecting factor system of theproject cost management by organizational environment, is built by these factors.Tab.1. the Affecting Factor System of the Project Cost Management by Organizational EnvironmentFirst class index Second class indexThird class indexProject CostManagementA Organization Structure 1B Organization Framework 1C Internal Coordination 2C Internal Restriction 3CControl System 2B Budget Mechanism 4CAccounting Mechanism 5CMonitoring Mechanism 6C Analyzing Mechanism 7CChecking Mechanism 8CMaterial Cost Management 9CProject Manager Management 10CSocialRelations 3B Major Stakeholder 11C External Communication andCoordination 12CEvaluation of the influence of the organizational environment on project cost managementbased on the Grey Relational AnalysisTo determine the weighing values of all levelsBecause of the important degree of the influence of the above indexes on project cost are notidentical, it is required to determine the weights.We can choose to invited several experts whoadopted the ratio scale method to compare two factors, and to determine the ratio scale betweenvarious factors, as shown in table 2, then in turn collect the statistics of frequency mij of each indexratio scale Cj.()jij C i j m U U c n= （2.1） In the formula, mij is the number of times of Ui ∈ci; n is the number of experts to participate inthe evaluation; Uci(Ui) is the ratio scale of Ui belong to the cj, we can get the ratio scale()j n i C i j i R U U ==∑ （2.2）986Tab.2. The meaning of the scaledivision meaning1 Have the same importance3 The former is a bit more important than the latter5 The former is obviously more important than thelatter7 The former is particularly more important than thelatter9 The former is extremely more important than thelatter2,4,6,8 The median value of the above-mentioned adjacentvaluereciprocal The degree that the latter is more important than the formerCalculate the feature vector W of matrix H, inspect whether have stochastic consistencybetween matrix H and the feature vector W, and compute consistency index CI=(λmax-n)/(n-1),when CR=CI/RI<0.10, the consistency of judgment matrix is satisfied, or need to adjust thejudgment matrix. Among them, the elements Wi(i=1,2,...n) of W represents the lower the weight ofeach index relative to its upper part index.Quantitative treatment of indicatorsEvaluation index can be divided into two types: quantitative index and qualitative index.Qualitative indicators are unquantitative fuzzy evaluation index, thus the comprehensive fuzzyevaluation method of quantitative index can be used. By experts fuzzy scoring in the first place,reoccupy the average value to quantify according to the fuzzy membership degree just as is shownin table 3.Tab.3. The fuzzy membership listfuzzy language best bette r goo d general ly ba d wors e wor stmembership 0.8 0.7 0.6 0.5 0.40.3 0.2 To determine the reference data sequence and compared sequenceIn order to evaluate the eligible object data sequence, the first thing is to determine theevaluation reference data sequence, usually write to uik=(ui1,ui2,...uin),k=1,2,...s.A comparison with reference data sequence uik have n data index sequences, and each datasequence (scheme) have s factors (indicators), then these comparative data column can be written asU0=(u10,u20,...un0)T.To determine the reference sequence, according to the comparison reference sequence types ofindicators selected, index of different types, different values of the methods. Seen in the literatureindex types have six kinds, including efficiency, cost, fixed type, range, deviation and deviationinterval[4].Index correlation calculation of index layerIn order to ensure the quality of modeling and get the right system analysis, the data must becarried out on the original data standardization transformation and data processing, so that thedimension can be eliminated and the data can be comparable. in correlation analysis, the mostcommon methods were used in data transformation are initial value transformation method, themean transformation method, full transformation method, unitary transformation method, multiplechanges, poor maximum transformation method, standardized method and interval valuetransformation method[4-5]. In this paper, using the standardized method for data processing, namely:,1,2,,k k i i i u x k s u == （2.3） 987In the formula, 0 means the reference solution.Corresponds to a sequence of reference data, there are a number of comparative data sequence,the ith comparative data with reference data sequences in the first k corresponding indicators of relative difference is the correlation coefficient, can be expressed as()0000min min max max max max 1,2,;1,2,k k i i i i k i k i ki k k i i i i i k X X X X X X X X i n k s ηξη-+-=-+-== （2.4）Type: η is distinguish coefficient, 0<η<1, typically take η=0.5.The weighted average correlation coefficient under various factors11(1,2,;1,2,)n k k k i k n i n k s γωξ====∑ （2.5）Type: ωk is the weight, 0≤ωk≤1.According to the comparison and analysis of correlation, multi-level comprehensive evaluationof the construction project cost management is adopted. Generally speaking, the bigger thecorrelation of engineering project cost management level was, the engineering project costmanagement situation greater. In this way, we can made a more objective comprehensiveevaluation for the construction enterprise project cost management situation, and use this asreference data for the management of engineering project cost.ExampleNow with the influence of A, B, C three construction enterprise environment present situation onthe engineering project cost management as an example to illustrate the specific application ofevaluation model of gray association analysis.The index classification, the classification and the weight of each index of A, B, C threeconstruction enterprise organizational environment , are shown in table4 the comprehensiveevaluation of engineering project cost management.Tab.4. The project cost management comprehensive evaluationLevel indicator s The weigh t The second Level indicators The weig ht the index sequence of Project cost management evaluation A B C 0i uB 10.3 C 1 0.4 0.4 0.6 0.5 0.6C 2 0.3 0.5 0.7 0.6 0.7 C 3 0.3 0.6 0.7 0.5 0.7B 20.4 C 4 0.2 0.7 0.6 0.4 0.7C 5 0.15 0.7 0.6 0.5 0.7C 60.1 0.6 0.5 0.5 0.6 C 7 0.2 0.5 0.5 0.6 0.6 C 8 0.1 0.6 0.5 0.5 0.6C 9 0.12 0.6 0.6 0.7 0.7C 10 0.13 0.6 0.5 0.5 0.6B 3 0.3C 11 0.56 0.7 0.6 0.6 0.7 C 12 0.44 0.5 0.5 0.6 0.6Weight is index to describe the affection of properties and various indicators of project costmanagement evaluation , scored by the expert , calculated the weight according to the type 2.1, 2.2 ,through the consistency check, in view of the length, not do detailed calculation here.Determine the optimal index (reference sequence)According to the principle of determining the optimal index, we can determine the referencesequence 0(0.6,0.7,0.7,0.7,0.7,0.6,0.6,0.6,0.7,0.6,0.7,0.6)i u =988Data standardization processBy the evaluation index system of project cost management, the evaluation index points belongto three classes. Processed the index sequence standardized according to the type (2.3) , threeclassification subset sequence are obtained. Calculate the absolute difference between the evaluation and the reference sequences sequencematrix, the calculation results are as follows:1max 0.33B ∆=，1min 0B ∆=；2max 0.17B ∆=，2min 0B ∆=；3max 0.43B ∆=，3min 0B∆=. Evaluation of the primary engineering project cost managementTake the resolution 0.5η=, the correlation coefficient of each subset can be calculated accordingto the type (2.4) , and correlation coefficient matrix is established. The table 4 shows that for Ⅰindexes, the weights 12(0.4,0.3,0.3)B ω=. According to the type (2.5) , he correlation of this indicator canbe calculated. [][]11120.330.370.541110.40.30.30.4110.470.50.540.37T B B B γωξ⎡⎤⎢⎥=⋅=⋅=⎢⎥⎢⎥⎣⎦On the basis of above, the primary evaluation can be conducted. For the class index, the sort ofthree construction enterprise correlation is C > B > A, which the index of engineering project costmanagement of construction enterprises B is optimal, C construction enterprise take the second, Abusiness is the worst.Similarly for II indexes, []20.790.350.5B γ=, we can judge that the optimal is A enterprise and Benterprise is the worst. For III indexes, []30.810.580.58B γ=, we can judge the optimal is A enterprise, B and C enterprise is the same.According to the corresponding evaluation results, management of construction enterprise projectcost management is optimized.The secondary comprehensive evaluation of the gray correlation analysisFrom the primary evaluation,we can be see that in the category of different indicators of thesame construction enterprise, both the optimal and the worst index category of engineering projectcost management can be appeared. Obviously , it is difficult to reflect the overall condition of theengineering project cost management. Therefore, all categories should be considered to thesecondary comprehensive evaluation on engineering project cost management. Primary indexweights ω1=(0.3,0.4,0.3), according to the type (2.5) ,we can get comprehensive correlation degree [][]10.410.790.8110.350.580.30.40.30.680.610.520.470.500.58T A γωξ⎡⎤⎢⎥=⋅=⋅=⎢⎥⎢⎥⎣⎦ Order By the correlation size:A B C γγγ>>. As you can see, the construction enterprise project costmanagement situation of quality for A is the best, B enterprise second, C enterprise is the worst.ConclusionBased on actual engineering project cost management, this paper considers the organizationalenvironment factors and builds the organization environment factors to the engineering project costmanagement. With gray correlation analysis method to engineering project cost managementconducts a multi-level evaluation, obtains different levels of management evaluation results, theresult is consistent with the actual situation of construction enterprise.shows that this method hascertain theoretical significance and practical value. But in this study, the main factors affecting theproject cost management may have failed to be included in some factors, such as enterprise culture,national macro policy and other factors. In future study, we can further complete factors through thedesign organization environment impact on the engineering project cost of questionnaire.989References[1] XuTang.Based on the strategy of target cost management method in the application of international engineering contracting project .Chong qing.Southwestern university of finance and economics , 2003:6-7.[2] Kaplan,Norton.Strategic center type organization. Beijing:Ren min university of China publishing house,2001.[3] Yan Haifeng,Wang Ruixu.The modern organization theory and organizationinnovation.Beijing:People's posts and telecommunications publishing house,2003:61-81.[4] Wu Weidong , Jing Guoxun,Wei Jianping. Grey correlation analysis in six coal mine ventilation system scheme (recent) the application of the optimization . Journal of coal , 2001, 34(3): 290-293.[5] Xiao Xinping, Song Zhongmin,Li Feng.Gray technology base and application.Beijing: Science press.2005.990。

AbstractProject cost management is the basic contents to determine reasonable and effective control of the project cost. Described the current stage of the project cost management situation on the strengthening of the various stages of construction cost management of the importance of and raised a number of key initiatives.Keywords：cost of the construction project cost management status investment decision phase of the design phase of the implementation phase of the cost management in a market economy.Even under the WTO and China's accession to the world community, China's construction industry how to effectively control construction cost of the construction and management of an important component part. However, the current budget for the construction projects - estimate, budget, Super budget accounts for the "super three" is still widespread and that eventually led to a serious loss of control of project investment. Project cost management is the basic contents to determine reasonable and effective control of the project cost.As the project cost to the project runs through the entire process, stage by stage can be divided into Investment Decision stage, the design and implementation phases. The so-called Project Cost effective control is the optimization of the construction plans and design programs on the basis of in the building process at all stages, use of certain methods and measures to reduce the cost of the projects have a reasonable control on the scope and cost of the approved limits.Engineering and cost management work of the current status of project cost management system was formed in the 1950s, 1980s perfect together. Performance of the country and directly involved in the management of economic activities. Provisions in the design stage to different estimates or budget preparation as well as government; Nothing relevant departments to formulate a budget, content, methods and approval, the budget will provide the fixed cost of equipment and materials and fixed price of the budget preparation, approval, management authority, and so on.With the historical process, after recovery, reform and development, formed a relatively complete budget estimate of quota management system. However, as the socialist market economic development, the system's many problems have also exposed. Generally speaking, the budget estimate is based on direct participation in the management of national economic activity as a precondition. enterprise is not the actual economic entities. Due to the characteristics of the planned economy, and, at the time under the conditions of productivity, will inevitably become a shortage in the economy.In severe shortage of commodities under the conditions, as long as a certain level of investment, will be certain outputs. In this environment, the project planning and technical argumentation there can be no economic analysis. State control of the project cost constitute key factors equipment and materials prices, wages and taxes of artificial distribution. In this relatively stable economic environment, the budget estimate for the system approved project cost, help the government to carry out investment plans to play a major role.As the socialist market economic system established, requires us to predict project investment and control. In recent years, international investment project developed to the requirements of prior pre-control and in the middle of control. China, the traditional practice in an objective light on the cause decision-making, implementation heavy, light the economy and technology,First, the consequences of victimization,Due to the technical personnel of the project technical and economic concepts and a weak awareness of cost control, cost management makes the quality difficult to raise. Project Cost control is difficult to achieve long-term goals.Second, the various stages of the project management view of the above circumstances, My first academia in the 1980s made the whole process of cost management and control concept, building departments will study the feasibility of projects and the budgets and final accounts to two extended at the request of the corresponding regulations put our cost management concepts and methods referred to a new height.Our task now is to be modern and cost management in line with China's national conditions of the market economy system goal, learn from the advanced experience of the developed countries, and establish sound market economic laws of project cost management system, efforts to increase the project cost levels. An investment decision-making phase of the project cost management construction project investment decision-making stage is proposed project proposals; conduct a feasibility study to determine investment estimation and the final preparation of design task. At this stage, the project's technical and economic decision-making, of the construction project cost of the project after the completion of the economic benefits have a decisive influence, The construction cost is an important stage control.China's current stage of the project cost for the project management for the purpose of clearing price, and focusing only on the construction process of cost control, neglected before the start of the project investment decision-making stage of cost control. Investment decision-making phase of investment projects is estimated an important basis for decision-making. It has a direct impact on national economic and financial analysis of the results of the reliability and accuracy. Because of this phase is the preliminary work of projects, the information can not be fully, comparable works more or less that information accumulated relatively small, estimated inadequate and unscientific. Makes project cost management and cost workers is difficult at this stage do something.The various stages of the project cost control in the decision-making phase project cost control. Right project planning phase of the cost, many owners have the wrong understanding that the lower the cost the better. Cost control is not a unilateral issue, and should be a number of factors, a combination of practical, comprehensive consideration. The construction project investment decision-making stage, the project's technical and economic decision-making, Cost of the project after the completion of the project and the economic benefits, with a decisive role in project cost control is an important stage, rationally define and control the direction of the project cost of accurate positioning and building Optimization guiding role.In the decision-making phase of the most important is to do a good job feasibility study, the work is done well, returns on investment and can form a good proportion. Otherwise, invest more, less effective, resulting in loss of control and waste of investment.At present, some of the projects planned the owners of departure from the subjective desires of a feasibility study on the lack of scientific proof. Feasibility Study untrue, false or engineering functions obtaining the approval of their superiors, actually put into the feasibility study will be awarded in the study for the project after the smooth functioning buried a lot of hidden problems, lead to insufficient follow-up funds for the project and had to extend the time limit so that the project could not have planned the use of cost-effective, even become hopeless completion of the beard works.Therefore, in order to phase in the investment decision-making effectively control construction costs, we must do the following aspects:ⅰImplementation of the construction project and corporate accountability, Construction of the project from planning to implementation of the entire process and the use of the funds to repay responsibilities to the people. in addition to establishing a legal system and the project supervision matching mechanism by the departments in charge of the industry and supervision departments for setting up a monitoring group to oversee the use of funds.ⅱA realistic approach to market analysis, to avoid the blindness of the project decision-making, reduces and reduces investment risk. Fully consider building projects in the future market competitiveness, design task more scientific and reliability.ⅲCapital financing must have a formal commitment document, the parties must do investment funds in place, and funds must have documents to ensure that the project can be approved after the scheduled implementation. To the various loan conditions should be carefully analyzed to minimize the burden of interest and repayment pressure.ⅳTo strengthen the engineering geology, hydrology, geology and land, water, electricity, transport, environmental projects such as external conditions for the work of depth to make the investment estimate there are sufficient grounds.Taking extensive investigation and research, comparison of similar projects, seriously functional analysis, multi-program comparison and choice. After full technical appraisal and economic evaluation, and the final technologically advanced, functional and reliable. Reasonable economic projects, thus calculate a more accurate and realistic estimation of the amount of investment, so that the project cost from the start positioning in a more reasonable level.The design phase of the project cost control for a long time, China's building control very effective, - investment projects is not uncommon, this will affect owners of investment returns, it adds to the owners and within budget, as well as difficulties in fund owners, the impact on the future management or the owners make payments in arrears, and so on. Hence, the control of the project cost is of great significance, however the project cost is the primary means of control design,Currently most of the property owners in the design stage seldom works on cost control, and they found that the cost of the design will not have a great impact, it is wrong, on the contrary, Design phase of the project cost control is the most important step. Because it determines engineering design, construction methods, materials and equipment types, models of the project cost is of critical significance, design optimization phase of the program or minor changes, project cost will have a significant impact, Design phase of the project cost control of the total project cost of 70%. Following is how to control the project from design to create the Law: ⅰAs the owners must design, the design selected on the quality level is a direct impact on the quality of product design level, and the design quality products in the level of direct influence on the pricing of the works. Different design units on the same project design are different. the same item of different design institute works between certain aspects of the project cost on the existence of differences between, We assume that with a design from two different design institute to design, Construction plans after the completion of a requested advisory unit cost to do thebudget, certainly different design institute the total cost of the project is absolutely not the same, and most of the difference between the two over 10% even more than 30%, and not necessarily high cost than the design of low cost, and good design is often low cost, We all know that different people have different design styles and different levels, the design works naturally, therefore chosen to design units is the control on the first step. Through tender to select the design of the units is a good method, the tender documents to elaborate on this particular aspect of the requirements, cost control targets, and so on.Otherwise, in the subsequent design process design units will put an increase in the cost of the design requirements; through tendering the project design into the market, compared to select the best design units.ⅱPromoting the design bidding and design optimization campaign mode design units assessed by experts using scientific group France, in accordance with applicable, economic, aesthetic principles and advanced technology, reasonable structure to meet building energy efficiency and environmental requirements, comprehensive assessment of the merits of the program design, selection of the best determination of the successful program.Successful investment program estimated to be close to the general construction project scope of investment. This means two design contracts will help design the program of choice and competition to ensure that the selected design advanced technology, unique novelty, adaptability, as well as to control the cost of the project. Design units should strive to improve their quality of the project design clever idea, contemporary reducing the project cost on to rack their brains to improve design quality, strive to put the design phase of the project cost control approval of the investment ceiling.ⅲStrengthening the design stage of the design phase to strengthen supervision of the Commissioner to determine a reasonable design, mature technology, reduction in the construction phase major design changes and changes in the program, in the effective control of the project cost will play a role. 1 to the design of the project if the project supervision to get involved, excluding unfavorable factors may generally isexcluded from the 80% errors. In the entire process of building cost control, construction began at best to save and invest 20%, the key lies in the construction phase of the identification and control costs. Supervision of the design phase include : Design Institute under the design drawings and notes help owners deal with different design options for the economy, capital expenditure to develop the preliminary estimates, to ensure that the investment can be most effectively utilized. With the owners of the Commissioner include:According to the Design Institute to provide design drawings and notes to help owners deal with different design options for the economy, capital expenditures to develop the preliminary plan to ensure that investment can be most effectively used; with the owners of different design options, the need to calculate their own materials and equipment to conduct a cost analysis and study, to the design staff costs, to assist them in the investment limit within limits designed to save and invest. To seek aone-time small investment and economic good design program made the most rational economic indicators.ⅳDesign actively promote the so-called cap limit design, even with the approval of the design task and investment estimates, guarantee the functional requirements of the premise. The preliminary design and control budget, according to the preliminary approval of the total budget for the design and construction design control. Limits, and every one professional, each of whom have a design threshold of a target. In the design process, designers should progress to more programs, design optimization, ensuring that the design is technically advanced and reasonable, innovative, stylish, and do not break the limit investment objectives, thus eliminating the engineering design raise the factor of safety and design standards, or only consider the technical feasibility of the program, rather than economic rationality phenomenon, the project cost to ensure effective control.Also known as the value of value engineering analysis, is a modern scientific management technique, is a new techno-economic analysis, is the product of functional analysis to conserve resources and reduce the cost of the purpose of an effective method. It made up for the traditional cost management simply focus on costreduction and quality management only emphasizes improving the quality deficiencies, construction is conducive to resolving the long-standing long period, a lot of wastage, poor quality, high-cost problems. Value Engineering laws generally divided into three steps: assessment of the design of object technology and economic Score; Calculation of the target group of technical and economic indicators; calculate the geometric design of the object, on average; from comparison choose the best design.1985 summary, project cost control is a whole process of control, it should be said that every link is no room for complacency, and each one links are also important. With China's entry into the WTO, China was the main investment diversification, investment side of cost reduction, cost control, improves returns on investment increasing attention. Therefore, changes to the original construction cost estimate, budget, budget, contract prices, and the settlement price accounts for the completionof the move. Lack of continuity of the situation, the launch control system investment projects, investment in construction projects to improve the level of control. Can promote the country's socialist market economic development, adapt to the global economic integration process.摘要工程造价管理的基本内容,确定合理和有效控制工程造价。

工程造价毕业论文摘要（中英）第一篇：工程造价毕业论文摘要(中英)扬州职业大学毕业设计（论文）中文摘要摘要清单计价模式在世界上有很广泛的运用，在我国也正在取代定额计价模式成为主流，中国的政策法规规定，凡使用国有资金投资的工程项目必须采用清单计价模式，其他情况下的工程项目具体是使用清单模式还是定额模式由建设单位自行决定。

保留定额计价是考虑到我国实际情况而作出的一种过渡性安排。

本毕业设计通过西部小街运河家园15#楼的工程为实例，进行了工程计量计价。

使用未来清单编制软件、Excel、天正建筑等软件，结合学习的知识及中国现阶段的计价模式，通过定额与清单模式的编制、成果对比，熟悉了招标控制价、投标报价的编制过程，深化了对造价工作的认识与运用。

关键词：清单计价，定额计价，招标，投标，成本管理扬州职业大学毕业设计（论文）中文摘要ABSTRACTBill valuation mode is used very widely in the world, in China is also being replaced by the tradition mode of rating valuation to become the popularity, according to China's policies and regulations, investment and the use of state capital projects must adopt the mode of valuation with bill, other project case specific is the use of list mode or quota mode is decided by the construction unit itself.Reserved quota valuation is a transitional arrangement in consideration of China's actual situation and make.The graduation design through the Western Street Canal homes 15# building project as an example, the engineeringvaluation.The use of future listed software, Excel, TarchCAD building software, combined with the pricing mode of learning knowledge and the present stage of China, by contrast, quota and compiled list mode results, familiar with the process for the preparation of tender control price, bidding, deepen the understanding and application of the cost of work.Keywords：bill valuation, quota valuation, invitation for bid, bidding, Cost management第二篇：毕业论文摘要(中英双语)摘要企业发展战略就是企业为寻求和维持持久竞争优势而作出的有关全局的筹划和谋略，企业要在激烈的市场竟争中适应环境的变化，准确、有效地把握在环境变化中不断涌现的机遇和商机，并不断得到发展壮大，必须有明晰的企业发展战略。

本科毕业论文外文文献及译文文献、资料题目China’s Pathway to Low-carbon Development 文献、资料来源：Journal of Knowledge-basedInnovation in China文献、资料发表（出版）日期：V ol.2 No.3, 2010院（部）：管理工程学院专业：工程造价班级：姓名：学号：指导教师：翻译日期：2012.5.28外文文献China’s Pathway to Low-carbon DevelopmentAbstractPurpose–The purpose of this paper is to explore China’s current policy and policy options regarding the shift to a low-carbon (LC) development.Design/methodology/approach – The paper uses both a literature review and empirical systems analysis of the trends of socio-economic conditions, carbon emissions and development of innovation capacities in China.Findings –The analysis shows that a holistic solution and co-benefit approa ch are needed for China’s transition to a green and LC economy, and that, especially for developing countries, it is not enough to have only goals regarding mitigation and adaptation. Instead, a concrete roadmap towards a LC future is needed that addresses key issues of technology transfer, institutional arrangements and sharing the costs in the context of a global climate regime. In this light, it is argued that China should adopt an approach for low-carbon development centred on carbon intensity reduction over the next ten years.Originality/value –The paper thus provides a unique summary, in English, of the arguments supporting China’s current low-carbon innovation policies from one of the authors of this policy. Keywords：Carbon, Sustainable development, Environmental management, Government policy, ChinaPaper type – Research paperClimate change has become the most significant environment and development challenge to human society in the twenty-first century. Responding to climate change is the core task to achieving global sustainable development, both for today and for a rather long period of time from today. International negotiations on prevention of global warming and related actions not only concern the human living environment, but also directly impact the modernization process of developing countries. Although the process of global climate protection depends on the consensus of our scientific awareness, political wills, economic interests, society’s level ofacceptance, as well as measures adopted, a low-carbon (LC) development path is, undoubtedly, the critical choice of future human development.The science basis of climate change and its extended political and economic implicationsGlobal warming of the climate system has become an unequivocal fact. According to a large amount of monitoring data, global average land surface temperature has risen 0.748C over the last century (IPCC, 2007a, b, c, d). And the rate of rising has been sped up. In the meantime, global average sea level has been constantly rising too. Global warming has posed a serious challenge to Chin a’s climate, environment and development. In the global context of climate change, China’s climate and environment are changing too. For instance, in the last century, the land surface average temperature has witnessed an obvious increase; though the precipitation has not changed too much, its interdecadal variations and regional disparity have been big. In the last 50 years, there have also been major changes in the frequency and intensity of extreme weather and climate events (Editorial Board of China’s N ational Assessment Report on Climate Change, 2007).The IPCC (2007a, b, c, d) integrated assessment shows that since 1750, human activities have been a major cause of global warming, while in the last 50 years, most of the global warming is the consequence of human activities, with a probability of more than 90 per cent, in particular from the greenhouse gases (GHGs) emissions due to the human use of fossil fuels. It is forecast that before the end of the twenty-first century, global warming will continue, and how much the temperature will rise depends on what actions humans will take. According the Third Working Group Report of the IPCC fourth Assessment (IPCC, 2007a, b, c, d), human actions to mitigate climate change are feasible, both economically and technologically. Actions to deploy key mitigation technologies in various sectors, adopting policy and administrative interference and shifting the development pathway could all contribute greatly to mitigation of climate change.With China becoming the world’s largest CO2emitter, China faces increasing pressure to reduce its emissions. Being a responsible country, China will take actions to tackle climate change. When developing its mitigation target, China will consider such factors as level ofdevelopment, technology know-how, social impact, international image and a new international climate regime underpinned by fairness and effectiveness. China will move into a win-win development path to achieve climate protection, quality economic development and other related policy targets.To develop LC economy – background, opportunities and challengesAs illustrated above, systematic solutions are required to tackle climate change, due to the complexity of the global climate system as well as its coverage of broad social and economic issues. After nearly two decades’ exploration, human society has realized that in order to effectively mitigate and adapt to climate change, we have to fundamentally reduce our reliance on fossil fuels, which means that we have to achieve the shift to a LC future from the way we produce and consume to how global assets are allocated (including industries, technology, capitals and resources) and how they are transferred. From the perspective of the limited storage capacity of GHGs in the climate system as a global public good, both a high level of human wisdom and a new international climate regime to deal with market failure are required, which also demands the participation of all stakeholders and together they shall charter a new development pathway. Human society has to pay the economic prices to solve climate warming. Thus, the three flexible “mechanisms” in the Kyoto Protocol ( joint implementation, emissions trading and clean development mechanism) demonstrate a meaningful experiment for the Annex I countries to decrease their emissions reduction costs. What is needed is to move forward from where we are now to explore a more universally applicable mechanism that would effectively allocate the resources among the key responsible stakeholders. The LC development path embodies an integrated solution strategy. It aims to build up a LC society through LC economic development, tries to achieve the restructuring of all the key elements discussed above and offers new opportunities for human society in response to climate change through collaborations.As a fundamental venue to coordinate social and economic development, guarantee energy security and respond to climate change, development of LC economy is gradually gaining the needed consensus from more and more countries. Though without a fixed academic definition, the core of developing a LC economy is to establish a development pathway that has high-energyefficiency, low-energy consumption and low emissions. Under a fair and effective international climate regime, the efficiency of energy exploration, generation, transmission, transformation and use is expected to be increased greatly and energy consumption greatly reduced, so that the carbon intensity in energy supply for economic growth is dramatically reduced, along with the carbon emissions from energy consumption. Through increasing carbon sink and using carbon capture and storage (CCS) technology, the GHG emissions from fossil fuels that are hard to reduce can be offset. In the meanwhile, through the establishment of reasonable and fair technology transfer and financial support mechanisms, developing countries can undertake the costs of shifting towards LC patterns while being at the lowest end of the value chain in the international trade structure. The perspectives of development value need to be changed in order to promote the transition of consumption towards a sustainable and LC future.What needs to be clarified is that, due to the differences of various countries’ social and economic contexts, the starting points towards a LC future might vary, as might the pursued goals. For developed countries that are taking the lead to commit to reduction targets, their first objective to develop a LC economy is to reduce emissions. For developing countries whose economies are still at a fast growing stage, their first priority is development and their per capita energy consumption is expected to continue to grow. The objectives shall be multiple. At the current stage, it is hard to mainstream the climate change policies domestically. What is possible is to reduce energy intensity and increase carbon productivity in order to gradually decouple economic growth and carbon emissions. What is equally important is that there exist many uncertainties in development of LC economy, particularly for developing countries. Tremendous difficulties and barriers need to be overcome in the process. At the international level, the uncertainties of developing LC economy include:Costs and markets – at this moment we could hardly be able to estimate the whole costs that are required to develop a LC economy. It is far from being as simple as calculating the direct costs of adopting LC technologies. It also takes time to establish LC technology and product markets, especially now, when the global financial crisis has hit everyone hard and when no one can give a good estimate about when the world economy could turn around and recover; though many experts and scholars hold that the response to the long-term climate change could bring new opportunities to economic recovery (Stiglitz, 2009; Wang, 2008b). What makes the situationmore complicated now is how the USA, China, India and other key countries would participate in the establishment of a LC market.Establishment of a fair international climate regime and mid- to long-term targets to tackle climate change – the development of a LC economy also depends on the international climate negotiation process and its result, of which the most critical element is whether it will result in legally binding global emissions reduction targets and the corresponding mechanisms of technology transfer and financial support, even if this was not established at Copenhagen.To date, even though some EU countries have achieved the decoupling of economic growth and carbon emissions, LC economy has not generated universally applicable, successful experiences; and what those experiences mean to developing countries still needs to be figured out and tested overtime.For developing countries, the difficulties and barriers to devel oping a LC economy are obvious, including current stage of development, international trade structure, economic costs, inadequate market, technology diffusion system, institutional arrangement, incentive policy and management system. From the historic evolution of the relationship between economic growth and carbon emissions in industrialized countries, most countries experienced successively the inverted U-shape curves of carbon intensity, per capita carbon emissions, and then total carbon emissions. But different countries or regions vary greatly in economic development level or per capita gross domestic product (GDP) relative to the carbon emissions peak. This shows that there does not exist a single, exact turning point between economic growth and carbon emissions. If you examine those countries or regions that have passed the carbon emissions pe ak, roughly 24-91 years, on average 55 years, are required between the peak of carbon emissions intensity and that of per capita carbon emissions. Some driving forces to reach different peaks have been shown in Figure 1 in terms of experience in the past and scenario analysis in the future. The point is, without strong mandatory emissions reduction measures and external support, developing countries will need relatively longer time to reach the peak of carbon emissions growth and then stabilize and decreaseStrategic measuresOn the basis of the above-mentioned analysis, the LC path with Chinese characteristics shall also focus on gradually setting up “resource-e fficient, environment-friendly and LC-oriented” society. Guided by LC development strategy and its targets, efforts shall be made to develop relevant institutional arrangements, improve management systems, stipulate development plans, accumulate experience from demonstrations and pilots, and push forward LC economic development in an orderly manner, so that a sustainable and LC future can be shaped for China. Four major aspects are the key starting points to structure a LC social and economy system:(1) Establish a legal and regulatory framework addressing climate change and improving the macro-management system. The legislative feasibility and legal model of “Law to Address Climate Change” shall be debated and articulated. Also, in the legislation process of other laws and regulations, articles related to response to climate change shall be included. For instance, a technical guideline of strategic environmental assessment shall include articles related to climate change impact assessment. A legal and regulatory framework of responding to climate change will gradually emerge. Owing to the fact that China’s administrative authority in charge of climate change remains weak and lacks capability, first, the Leading Group of the State’s Response to Climate Change and Energy Saving and Pollution Reduction Work shall play its full roles when a more flexible and diverse departmental coordination mechanism is established; and the group shall put forward strategic measure recommendations in response to climate change. Second, capacity building shall be strengthened and more administrative resources shall be allocated, so that better preparation is made for the next round of government restructuring to further improve the administrative level of the government department in charge of climate change.(2) Establish long-acting mechanism framework of LC development and stipulate related LC development policies in an orderly manner. Institutional innovation is the key to embarking on a LC development path. China shall become more pragmatic in developing a long-term incentive mechanism and policy measures that are in favour of energy saving, environmental protection and climate protection, guided by the balanced development framework and achieve the LC transition at government and business levels. At this moment, many regions and citieshave expressed their interest and enthusiasm toward LC development. As well as the complexity of LC economy and the diversity of models, related guidelines shall be rolled out to guide the macro policy and regulate the content, model, direction of development and assessment indicator system of a LC economy. Experiences and lessons from other countries can be examined and learned in order to move forward LC development in an orderly and healthy manner. Special planning and programs shall be developed at national level, and then some representative regions and cities, as well as some key sectors, can be selected for LC piloting purpose. When the market matures, LC markets shall be set up through regulating the pricing mechanism and stipulating fiscal and incentive policies.(3) Strengthen collaboration and establish a healthy LC technology system. Technological innovation is the core element in LC development. Government shall adopt integrated measures to offer a relaxed and favourable policy environment for business development and create and provide better institutional guarantees for technological innovation. As a result, the R&D and diffusion of high-energy efficiency and LC emissions technologies can be strengthened in both production and consumption. A diverse LC technology system will be gradually built for energy saving and energy efficiency, clean coal and clean energy, renewable energy and new energy, as well as carbon sinks. The level of commercialization will be improved. Thus, a strong technological foundation will be provided for LC transition and shift in the ways of economic growth. China shall also further strengthen international collaboration, not only through the climate-related international cooperation mechanism to import, absorb and adopt advanced technologies from other countries, but more importantly, through participating in the stipulation of related internation al sectoral energy efficiency standards and standard of carbon intensity, as well as benchmarking. China could consider voluntary or mandatory benchmarking management to elevate some key LC technologies, equipment and products to international leadership level.(4) Establish collaboration mechanism with all stakeholders’ participation.Low-carbon development is not just for government or business; instead, it requires all related stakeholders’ as well as the whole society’s participation. Owing to the fact that there exist some inadequacies in the general public’s awareness of climate change, publicity, education and training are required in combination with policy incentives to transform the public’s perception and thinking, increase the public’s awareness on response to climate change and gradually reach consensus on focusing onLC consumption behaviours and models. Joint actions with all the stakeholders are needed to resist the potential risks from climate change.References：EIA (2008), International Energy Outlook, EIA, USDOE, Washington, DC.He, J. (2008), “Addressing climate change through developing low carbon economy”, Keynote Speech in Sino-Danish Forum on Climate Change, Beijing October 23. IEA (2008), World Energy Outlook 2008, IEA, Paris.IPCC (2007a), Climate Change 2007: Impacts, Adaptation and Vulnerability, available at: www.ipcc.chIPCC (2007b), Climate Change 2007: Mitigation of Climate Change, available at: www.ipcc.ch IPCC (2007c), Climate Change 2007: Synthesis Report, available at:www.ipcc.ch/pdf/assessment-report/ar4/syr/ar4_syr.pdfIPCC (2007d), Climate Change 2007: The Physical Science Basic, Cambridge University Press, Cambridge.Jiang, K. (2007), “A scenario research on China’s greenhouse gas emissions”,International Climate Change Regime: A Study on Key Issues in China, China Environmental Sciences Press, Beijing, pp. 8-24.Stiglitz, J.E. (2009), “Three ways to global economic recovery”, available at:/pl/2009-01-13/082317033320.shtmlWang, Y. (2008a), “A low carbon path with Chinese characteristics”,Greenleaf, No. 8, pp.46-52.Wang, Y. (2008b), Summary of Sino-Danish Forum on Climate Change: Not to Delay Climate Change Progress by Financial Crisis, available at: /news/gjcj/200810/t1981142.htm中文翻译：中国低碳发展的途径摘要：目的：这篇论文的是探索中国现存的政策和针对低碳发展政策的其他可选方向。

工程造价国外参考文献介绍随着国际贸易的发展和国际化程度的提高，工程造价的国际化程度也越来越高。

因此，掌握国外的工程造价理论和实践经验对于提升我们的工程造价水平具有重要意义。

以下是一些值得参考的国外工程造价文献：1. Construction Cost Management: Learning from Case Studies by Keith Potts这是一本非常实用的案例研究书籍，介绍了各种不同类型工程的成本管理技术和实践经验。

这本书涵盖了建筑、土木、机电、电力等各个领域的工程案例，对于工程造价实践者和学习者都非常有帮助。

2. Quantity Surveyor's Pocket Book by Duncan Cartlidge这本书是一本实用的参考工具书，介绍了工程造价领域的各种技术和术语。

该书主要包括诸如工程量计量、估算、成本控制和财务管理等方面的内容，是一本非常适合初学者和实践者使用的工程造价指南。

3. International Construction Contracts: A Handbook by William Godwin这本书是一本关于国际工程合同的权威参考书籍。

该书涵盖了国际工程合同的各个方面，包括合同类型、合同条款、合同管理和国际仲裁等方面的内容。

对于从事国际工程造价工作的人员来说是一本不可或缺的参考书。

4. Cost Management: A Strategic Emphasis by Edward Blocher这是一本关于成本管理战略的书籍，重点介绍了成本管理的核心概念和技术。

该书还涵盖了成本管理在不同行业和企业中的应用，对于掌握成本管理的基本原理和实践经验非常有帮助。

总之，以上这些工程造价国外参考文献都非常值得我们参考和学习。

通过不断学习和实践，我们可以不断提升自己的工程造价水平，更好地服务于工程建设和经济发展。

工程造价英语文献以下是一篇关于工程造价的英文文献：Title: Construction Cost Estimation Techniques: A Review Abstract:Construction cost estimation is a crucial process in the construction industry, as accurate cost estimates are essential for project planning, budgeting, and decision-making. This paper provides a comprehensive review of various construction cost estimation techniques that are commonly used in practice. The review includes traditional methods, such as the unit cost method, the square foot method, and the assembly method, as well as modern methods, such as parametric cost estimation, expert judgement, and statistical analysis. The advantages and limitations of each technique are discussed, along with their applicability to different types of construction projects. The paper also highlights the importance of considering uncertainties and risks in cost estimation, and provides an overview of risk assessment techniques that can be used in conjunction with cost estimation models. The review concludes with recommendations for future research in the field of construction cost estimation.Keywords: construction cost estimation, techniques, traditional methods, modern methods, risk assessmentIntroduction:Construction cost estimation plays a critical role in the success of construction projects. Accurate cost estimates are essential for project planning, budgeting, and decision-making. However, costestimation is a challenging task due to the complexity and uncertainty inherent in construction projects. In recent years, there has been a growing interest in developing and implementing new cost estimation techniques to improve the accuracy and reliability of cost estimates. This paper aims to review the existing literature on construction cost estimation techniques and identify their advantages, limitations, and applicability in different contexts. Methods:A systematic literature review was conducted to identify relevant studies on construction cost estimation techniques. The search was performed using online databases and academic journals. The selected studies were then analyzed and categorized based on the type of construction cost estimation technique they described. Results:The review identified several traditional and modern cost estimation techniques that are commonly used in practice. Traditional methods, such as the unit cost method and the square foot method, are simple and easy to apply, but they may lack accuracy and flexibility. Modern methods, such as parametric cost estimation and expert judgement, take into account more variables and can provide more accurate cost estimates. However, they require more data and expertise. The review also highlighted the importance of considering uncertainties and risks in cost estimation, and described various risk assessment techniques that can be used in conjunction with cost estimation models.Discussion:The review revealed that there is no one-size-fits-all costestimation technique. The choice of technique depends on the characteristics of the construction project, the available data, and the expertise of the estimator. Moreover, there is a need for further research to develop more accurate and reliable cost estimation models, as well as to improve the integration of risk assessment techniques into cost estimation processes.Conclusion:Construction cost estimation is a complex and challenging task. This paper provides a comprehensive review of various cost estimation techniques used in practice and highlights their advantages, limitations, and applicability. The review also emphasizes the importance of considering uncertainties and risks in cost estimation, and suggests areas for future research. By improving the accuracy and reliability of cost estimates, construction professionals can make more informed decisions and ensure the success of construction projects.。

【word版本下载后可任意编辑】Flow of estimating data in Sri Lankan building contractororganizationsWhen an estimator prices a bill of quantities, s/he collects, generates and assembles data (estimating data) for the purpose of establishing the cost of constructing the project. The data generated could be used by the contractor’s subsequent management functions, and the use of estimating data in the contractors’ post-tender management worthy of attention. Drawing information from ten case studies of the organization of Sri Lankan building contractors, this paper identifies the contractors’s management functions; management tasks; and management. It also establishes the flow of estimating data within and between the management functions. These flows highlight the substantial burden of re-work in the post-tender use of data. It is argued that the current format and presentation of estimating data in Sri Lanka are the major causes for such re-work. However, it was found that any revolutionary change to the conventional format would not be welcomed by the industry. Any new proposal should be developed within the limitation of acceptability to conventional practice. The recommendation is that the ‘unit rate’ is broken down to its cost com ponents of material, labour and plant. The breakdown of the unit rate would supply all the necessary data for direct use, thus reducing the re-work. Further research should be addressed to investigate the best format and structure of this breakdown. Keywords: Bills of quantities, case studies, data management, estimating, Sri Lanka.IntroductionOver the past four decades, many researchers have investigated the post-tender use of bills of quantities in contractors’ management. Alternative formats to the bil l of quantities have emerged such as: Elemental Bill (Department of Education and Science, 1957), Sectionalised Trades Bill (Nott, 1963), Operational Bill (Forbes and Skoyles, 1963), Bill of Quantities一Operational Format一(Skoyles, 1968), BPF System一Schedule of Activities一(British Property Federation,1983) and Builders’ Quantities (Pasquire and McCaffer, 1988). However, the conventional practice of preparing the bill of quantities, using the Standard Method of Measurement (Royal Institution of Chartered Surveyors,1988), is still the widely used standard for preparation of bills of quantities (Kodikara, 1990). This does not mean that the current post-tender use of bills of quantities is efficient when used in the management of a contract by a contractor (Skinner, 1981). The BOQ is a client’s document for the client’s purposes. This paper reports on an investigation undertaken in 1989 into the contractors’ use of estimating data. The aim of the work was to observe the flow of estimating data in Sri Lankan building contractor organizations, and to identify reasons for inefficiency in contractors’ data management. To achieve this ten organizations were interviewed using a structured questionnaire. he questions were phrased as guide lines, so that they would lead to discussions revealing contractors’ current practices, problems and suggestions. Sri Lankan building construction industry follows some of the procedures, standards and principles that are used in the UK industry, hence the management of work in Sri Lankan building contractor organizations reflect some of the methods that are adopted in UK. Therefore, findings may also be of value to the UK industry. Parallel works on UK contractors’ data management have been researched by Pasquire and McCaffer (1987).Definition of termsIn this paper, the following terms are used to describe the given meanings.Estimating dataThe data that are collected, generated and assembled by the estimator for pricing purposes are termed estimating data. Estimating data includes prices of resources, usages of resources, prices of sub-contractors and prices of bill items.Management functionsThe management work of a construction project is grouped according to recognizable major management functions. These are estimating, purchasing, planning, site management, and quantity surveying/financial control.Management groupsThe professionals who are responsible for the work of the management functions are defined as managementgroups. They are estimators, purchasers, planners, site agents, quantity surveyors and upper management. It should be noted that the management functions and management groups are not the same because any professionalmanagement group can undertake work in several management functions.Management tasksTasks which are directly related to procurement and execution of contracts are defined as management tasks. In this paper, only the most important and common tasks in each management function are established through consultation with the professionals in the industry..Data flowThe term data flow is used to describe the process of extracting, using, regenerating, amending and passing on of data by contractors’ staff.Re-workWhen data are used for a particular task by a management group they can be used either directly or with some re-work to suit the requirement. The re-work is any work such as modification, or grouping, or breaking up of data. By proper presentation of data, this type of re-work can be reduced and the re-work which still exists is called ‘less re-work’Investigation methodologyThe Sri Lankan building construction industry was surveyed in 1989 to observe and record the current practices and problems in data management. The survey comprised interviews and discussions with professionals to ten organizations. Each organization was visited between five and ten times, and their management staff were interviewed to establish and record their actual experience and knowledge. The case studies were planned in such a manner that they would represent the whole industry. Out of various sampling techniques , the judgement sampling method was selected because it was the easiest way of meeting both the research constraints and representativeness. In selecting the organizations the criterion was to judge the representativeness of the sample. The criteria were: ownership, size, type of work, experience and location of work. Categories were defined for each criterion to divide the organizations within the criteria.OwnershipGovernment or private ownership.SizeLarge一annual turn-over of 200 million Sri Lankan rupees or Medium一annual turn-over of 50-200 million Sri Lankan rupees or Small一annual turn-over of 50 million Sri Lankan rupees.Type of workConsultancy, and/or contracting, and/or client.ExperienceWell-established一Over 15 years of service or Average一5-15 years of service Newly formed一Under 5 years seance.Location of workWC一Within and around (within 25 km radius) the capital city (Colombo) or OC 一Outside the capital city.Management functions, tasks and groupsThe observation in relation to the use of estimating data could be generalized to the overall industry irrespective of the size, ownership, etc. Although there are number of options available, only the conventional standard method of measurement is used to prepare and price the BOQ for projects. Even for contracts which do not demand the presence of a bill (e.g. turn-key, design-and-build), an internal BOQ is prepared in conventional format for management of work. Management tasks undertaken in estimating, purchasing, planning, site management and quantity surveying are summarized under each section. Each management group uses estimating data for their management tasks in different management funclions. These data are then passed to the other management groups. Data flow between management groups, management functions and management tasks were examined in the case studies. It was observed that the use and exchange of measured data within and between management functions were complex. The estimating data were used with substantial re-work, hence thepresent format and presentation of these data can be seen as the major cause for the inefficient flow of data.Data flow。

中英文对照外文翻译(文档含英文原文和中文翻译)在斯里兰卡建筑承包商中建立的估算数据流当一个预算员在编写工程量清单时，为了计算建设项目的成本他会收集大量的数据。

收集的数据可用于承包商的后续管理，承包商在投标后的管理中使用这些数据时应格外注意。

本文从斯里兰卡建筑承包商的十个案例研究组织中得到的信息确定了承包商的管理部门、管理任务和管理团队，而且还明确了估算数据流在各管理部门之间和管理部门内部的功能。

这些数据流强调了在投标后进行修正数据的必要性。

人们认为当前估计数据的形式和描述数据的主要原因是为了在斯里兰卡的重新使用。

然而，人们发现任何传统格式的革命性变革都不会受行业的欢迎。

任何新的提议在可接受性的限制下的传统做法内被制定。

单位价格由材料消耗量、劳动力消耗量和机械设备消耗量组成，单位价格各组成量可以提供所有的数据供直接使用，因此减少了一些重复工作。

进一步的研究应该着手于单位价格的最佳格式和结构的组成。

关键词：工程量清单、案例研究、数据管理、评估、斯里兰卡。

简介在过去的四十年里，许多研究人员调查了工程量清单在承包商投标后的管理中的应用。

已经出现的可供参考的工程量清单格式：操作清单（教育部和科学部，1957），地方性贸易清单（Nott，1963），工程量清单-操作格式-（Skoyes，1968），BPF系统-活动日程-（英国房地产联合会，1983）和建造者的数量（Pasquire and McCaffer，1968）。

然而使用了标准的测量方法（皇家特许测量协会。

1968）的工程量清单在传统的实践准备过程中仍然被广泛用于标准的工程量清单的准备。

（Kodikarq，1990）。

这并不意味着在承包商投标后的合同管理中使用工程量清单是有效的（Skinner，1981）。

工程量清单是投标人在所获取的主要文件，本文是对在1989年的一项调查承包商评估数据所作的报告。

这项工作的目的是观察在斯里兰卡建筑承包商组织中的估计数量流，并确定承包商的数据管理效率低下的原因。