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Comparing the Dynamic Analysis of Energy Efficiency in China with Other Countries

Written By

Chenchen Yang, Feng Yang, Liang Liang and Xiping Xu

Submitted: 07 December 2011 Published: 17 October 2012

DOI: 10.5772/48589

From the Edited Volume

Energy Efficiency - The Innovative Ways for Smart Energy, the Future Towards Modern Utilities

Edited by Moustafa Eissa

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1. Introduction

The development of world economy is closely related with energy consumption. According to the economics research by Department of Agriculture of the U.S., since 2000, the energy consumption quantity begins to rise sharply at an average annual growth rate of 2.5% which approximates with the global real GDP (gross domestic product) growth. In China, the second largest economy in the world, this index increases by 15.1% in 2004. Excessive energy consumption, together with the environmental pollution, has become a huge threat to the sustainable development of human beings. Thus, the continuous pursuing for higher energy utilization has drawn the attention of many researchers.

There are three categories of indices to evaluate energy utilization summarized by Ang[1] which are thermodynamic indicators, physical-based indicators, and monetary-based indicators. Different with the first two indicators, outputs in monetary-based indicators are measured in form of currency. This causes monetary-based indicators popularly used in measuring energy efficiency of various levels, not only the common production process at the micro-level but also the comparison between countries at the macro-level.

Ang [1] introduces some key indices belonging to the category of monetary-based indicators. Energy intensity (EI), which is defined as the quotient of total energy consumption divided by total output (GDP or GNP), is used to estimate one’s energy efficiency roughly[1]. Energy coefficient is another index referring to the quotient of growth rate of total energy consumption divided by growth rate of total output, which is usually applied in comparison among various countries or regions [2]. However, the stability of energy coefficient is very poor, especially when the growth rate of one country’s GDP approaches to 0. Benefit for its clear definition, simple calculation and easily improvement, EI becomes the most frequently-used index in energy efficiency evaluation from both points of practice and research.

Most of literatures studying energy efficiency adopt energy intensity to analyze energy utilization efficiency, for instance, Howarth et al. [3] and Greening et al. [4], both of which are quoted frequently by other researchers. However, for simplicity, total energy consumption used in EI calculation only considers the sum of all kinds of energy consumption. EI neglects the structure of energy consumption, that’s why the index may estimate the energy efficiency inaccurately. Different energy storage capacities and consumption habits make energy consumption structure to be an indispensable influence factor in evaluation. In order to deal with this problem, Xu and Liang [5] introduced a weighted energy intensity model based on data envelopment analysis to evaluate the energy efficiency considering energy consumption structure.

Data envelopment analysis (DEA), a popular approach to evaluate the relative efficiency of homogenous decision making units (DMU) with multiple inputs and multiple outputs[6], has been widely used in the energy efficiency analysis and gained a lot of research achievement [7]. For example, in recent literatures, Mohammadi et al. [8] used DEA approach to evaluate energy efficiency of kiwifruit production in Iran. Rao et al.[9] developed an improved DEA model to analyze energy efficiency and energy savings potential in China. Bian and Yang [10] summarized several DEA models for measuring the energy efficiency and proposed an extended Shannon-DEA method to define a comprehensive concept of energy efficiency.

However, EI index based on DEA concentrates on the transforming degree of energy consumption to GDP or other economic statistical data, and ignores the function of non resource inputs such as labor and capital stock which also play an essential role during the production process. Boyd and Pang [11] introduced the concept of total factor energy efficiency (TFEE) and proposed a model to estimate the linkage between energy efficiency and productivity of the glass industry. References [12] and [13, 14] developed a series of models in estimating total factor energy efficiencies of 29 regions of China and Japan.

Except for using DEA model to analyze the energy efficiency at a given time, this chapter intends to investigate the dynamic change of energy efficiency over periods by adopting Malmquist production index (MPI) technique. First applied to study on the consumers’ behavior, after improved for many years, MPI approach deserves high praise in input-output analysis for the reason as follows: (1) no need for the price of input or output; (2) no need for the assumption of behavior pattern; (3) to get more intensive result of dynamic change easily[15]. MPI divides the total production growth rate into two parts, catch-up effect and frontier-shift effect, from which the cause of the change in energy efficiency can be clarified[16].

The current chapter tries to compare the total factor energy efficiencies of 48 countries all over the world in 2003 and analyze the dynamic change in total factor energy efficiencies of provinces of China over the period of 2000-2003 by the proposed model. The rest of this chapter is organized as follows. In Section 2, we introduce several methods for measuring the total factor energy efficiency and the dynamic change based on DEA and MPI technique. Section 3 shows how to use the proposed approach in analyzing the energy efficiency of 48 countries in 2003 and section 4 presents a dynamic example of total factor energy efficiency estimation of 30 provinces in china. Section 5 concludes this chapter.

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2. Methodology

2.1.Energy efficiency considering energy structure based on DEA model

Suppose that there are n homogenous decision making units (DMU) to be evaluated, denoted by DMUj (j = 1, 2, …, n). Each DMU consumes m type of energy inputs xij (i = 1, 2, …, m) to produce s types of outputs yrj (r = 1, 2, …, s).

Xu and Liangintroduced weighted energy intensity model (WEI) based on DEA to evaluate the energy efficiency considering energy structure. Energy efficiency of DMU0 is obtained by the following fractional programming:

max  h0=r=1sμryr0i=1mvixi0s.t.     r=1sμryrji=1mvixij1,   j=1,2,,n          μr,vi0,     r=1,2,,s;  i=1,2,,m.E1

In the empirical example, xij stand for all kinds of energy consumption like crude oil, natural gas, coal and so on while yrj are outputs. The vector of vi stands for the weights of the energy consumption xij which represents the energy structure. In addition, the vector of μr is the weight of the output yrj. According to DEA technique, DMU0 is efficient if there is a parameter bundle (vi, μr) making the target value equal to 1. The production frontier constituted by all of the efficient DMUs suggests an improvement direction to the non-efficient DMUs.

Halkos & Tzeremeshave noticed that the scale of countries has influence on the energy efficiency especially when estimating the various countries and regions[17]. Some small countries could be efficient under the condition of variable return-to-scale (VRS) as there is less restrictive[18]. Banker et al.[19] improved an extension based on the variable return-to-scale assumption by adding a convexity constraint.

Here we transform Programming (1) into an integral linear programming and add the VRS assumption. Then we obtain the following program:

min   θs.t.     j=1nλjxijθxi0,  i=1,2,,m.            j=1nλjyrjyr0,  r=1,2,,s.           j=1nλj=1,         λj0,                   j=1,2,,n.  E2

2.2.Total. factor energy efficiency based on DEA model

The concept of total factor energy efficiency investigates deeply into the energy consumption and production procedure and takes the non-resource inputs into account. As some representative examples, capital stock and labor are usually included. Following program is used to evaluate the total factor energy efficiency:

min   θs.t.     j=1nλjxijθxi0,  i=1,2,,m.            j=1nλjztjθzt0,  t=1,2,,p.            j=1nλjyrjyr0,  r=1,2,,s.           λj0,                   j=1,2,,n.  E3

Here ztj (t = 1, 2, …, p) stands for the non-resource inputs of DMUj. Adding the VRS assumption turns Model (3) into the following linear programming:

min   θs.t.     j=1nλjxijθxi0,  i=1,2,,m.            j=1nλjztjθzt0,  t=1,2,,p.            j=1nλjyrjyr0,  r=1,2,,s.           j=1nλj=1,         λj0,                   j=1,2,,n.  E4

2.3.Total. factor energy efficiency based on Malmquist production index

The above sections discuss the efficiency evaluation at a given time while this section presents the efficiency evaluating model during a period. Malmquist production index (MPI) is widely applied in measuring the dynamic variation trend of input-output efficiency by dividing the total efficiency into two parts, catch-up effect and frontier-shift effect [20]. Catch-up effect detects whether the efficiency of DMU makes progress during the period. If the numerical value of catch-up effect is more than 1, then we can make sure that the technical efficiency of DMU gets improvement and DMU is closer to the production frontier. Frontier-shift effect is used to assess the technique advancement which is measured by the transform degree of production frontier at different time-points. If the numerical value of frontier-shift effect is more than 1, it means the production technique of the latter is better than that of the former.

We assume that the production possibility set at time t, denoted by St, includes all of the feasible production bundles, input xt and output yt. For each time-point t, we have

St={(xt,yt):xt can produce yt}E5

And the input distance function at time t is

Dit(xt,yt)=sup{δ:(xt/δ,yt)St}=1inf{δ:(δxt,yt)St}E6

Following Färe et al. [21] and Boussemart et al. [22], the catch-up effect can be defined as

catchup=Dit+1(xt+1,yt+1)Dit(xt,yt)E7

WhereDit+1(xt+1,yt+1)means the efficiency of DMU(xt+1,yt+1)at timet+1and Dit(xt,yt) means the efficiency of DMU(xt,yt)at time t.

The frontier-shift effect is defined as

frontiershift=Dit(xt,yt)Dit+1(xt,yt)×Dit(xt+1,yt+1)Dit+1(xt+1,yt+1)E8

WhereDit(xt+1,yt+1)means the efficiency of DMU(xt+1,yt+1)at time t andDit+1(xt,yt)means the efficiency of DMU(xt,yt)at timet+1.

The Malmquist production index can be measured as follows:

MPI = catch-up × frontier-shift E9

We notice that there need four efficiencies to obtain the MPI and two of which can be obtained by the linear program (3). The other two efficiencies,Dit(xt+1,yt+1) andDit+1(xt,yt), can be measured by the following two models.

min θs.t.     λjxjt+1θx0t,         λjzjt+1θz0t,         λjyjt+1y0t,         j=1nλj=1,         λj0, j=1,2,,n.  E10
min θs.t.     λjxjtθx0t+1,         λjzjtθz0t+1,         λjyjty0t+1,         j=1nλj=1,         λj0, j=1,2,,n.  E11
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3. A comparative analysis of energy efficiency of 48 countries

In this chapter, energy efficiency analysis of 48 countries in 2003 is illustrated. The major countries and regions all over the world are included in our consideration such as the United States, China, Russia, Japan and so on. Primary energy consumption includes oil, natural gas, coal, nuclear energy and hydropower. We incorporate oil and natural gas consumption as the first part of energy input. Nuclear power and hydropower are incorporated as the second part of energy input. Coal is the third input. Labor and capital stock are adopted as the non-resource input. Gross Domestic Product (GDP) is the only output.

The data on energy input are collected from World Petroleum Yearbook (2004). GDP and labor are obtained from the World Development Indicators database (2003). Due to the unavailability on the data of capital stock of some countries, we use the index of adjust savings after consumption of fixed capital as a substitute. The data is available from the website of World Bank. All of the data collected are summarized in Table 1.

CategoryIndicatorsMaxMinMean
Energy inputsOil & natural gas1481.15.3105.62
Nuclear power & hydropower799.70.151
Coal242.80.222.27
Non-energy inputsLabor129483.9362.110208.44
Capital stock130128.1933.06
OutputGDP109486996828.9

Table 1.

Summary of inputs and output

Table 2 shows the results of energy efficiency considering energy structure measured by model (2). Countries in column 2 are ranked by GDP. The third column represents energy efficiency considering energy structure. Results indicate that: (1) there are 10 efficient DMUs including US, Japan, Italy and so on; (2) 21 countries’ energy efficiency scores lie on the interval of 0.5-1 and the typical countries are Britain, Germany, Mexico, etc; (3) the energy efficiency scores of the rest 17 countries are at very low level, less than 0.5; (4) the return-to-scale situation of most developed countries is in decreasing stage while in contrast many developing countries behave increasing returns to scale.

No.CountryWEI-VRSRankRTS
1United States1.00001D
2Japan1.00001D
3Germany0.908612D
4Britain0.996911D
5France1.00001D
6Italy1.00001D
7China0.339140D
8Canada0.347138D
9Mexico0.775518D
10Korea0.335941D
11India0.352636D
12Australia0.842216D
13Netherlands1.00001D
14Brazil0.293842D
15Russian Federation0.070748D
16Switzerland1.00001C
17Sweden0.856015I
18Austria0.766919D
19Turkey0.346939D
20Norway0.860114I
21Poland0.647922D
22Indonesia0.225645D
23Greece0.579326D
24Finland0.704721I
25South Africa0.490232I
26Ireland1.00001C
27Portugal0.583824I
28Thailand0.189446I
29Iran1.00001C
30Argentina0.489333I
31Malaysia0.292843D
32Czech Republic0.507330I
33Hungary0.548527I
34Egypt0.541728I
35Pakistan0.281844I
36Philippines0.580525I
37New Zealand0.711420I
38Columbia0.502531I
39Chile0.477734I
40Peru0.897213D
41Romania0.348837I
42Bangladesh1.00001C
43Ukraine0.109647I
44Slovakia0.636423I
45Kazakhstan0.509029I
46Bulgaria0.808417I
47Lithuania1.00001D
48Uzbekistan0.363735I

Table 2.

Energy efficienciesof 48 countries considering energy structure

It is particularly pointed out that the energy efficiency of China is only 0.3394 which is the worst among the top 10 countries ranked by GDP. The information of the input/output shown in Table 3 release that there are two reasons for that. First, the technical efficiency of energy consumption of china is lower, compared with Italy for example which has approximate output. Second, by comparison with 10 efficient countries, China has an improper construction of energy consumption that mainly relies on coal resource. Considering the heavy environmental pollution with coal’s burning, adjusting the structure of energy consumption is imperative.

No.CountryGDPOil & GasNuclear & hydropowerCoal
1Japan43009317.6112.275
2Ireland153712.11.60.2
3Bangladesh51915.20.40.2
4Netherlands511579.99.20.9
5France17576133.612.4114.6
6Italy14683156.615.310
7Iran1371126.40.72
8Switzerland320114.70.114.5
9Lithuania1825.30.13.7
10United States1094861481.1573.9242.8
11China14170304.7799.773.8

Table 3.

Input/output of 10 efficient countries and China

Table 4 represents total factor energy efficiency calculated by model (3) & (4). Countries in column 2 are ranked by GDP. Column 3 and 5 show two kinds of results due to the different setting-ups of return-to-scale. Column 3 indicates the total factor energy efficiency based on constant return-to-scale which can be viewed as pure technical efficiency. Column 5 indicates the total factor energy efficiency based on variable return-to-scale. The last column shows the status of each one’s return-to-scale. It is noticed that only five countries are efficient both in CRS and VRS. Quantity of efficient country in column 5 is more than that in column 3. Notice that the return-to-scale effect of top 14 countries in the table is in decreasing stage while most of the last 18 countries are in increasing stage.

It is interesting to analyze the situation of china. It can be observed from table 4 that China is in stage of decreasing return-to-scale effect and TFEE is ranked 30, still lower than all of the developed countries and most of the developing countries. This is mainly caused by lower technical efficiency shown in column 3. Therefore, there are at least 3 ways to enhance the total factor energy efficiency of China, including (1) improving the output of GDP, (2) re-arranging the allocation of energy inputs and non-resource inputs and (3) improving the technical efficiency of production.

No.CountryTFEE-CRSRankTFEE-VRSRankRTS
1United States0.865481.00001D
2Japan0.917761.00001D
3Germany0.8179101.00001D
4Britain0.8016111.00001D
5France0.6395171.00001D
6Italy0.889271.00001D
7China0.3139320.866330D
8Canada0.5787180.841731D
9Mexico0.7008141.00001D
10Korea0.3154310.782737D
11India0.3086330.889728D
12Australia0.6449160.902026D
13Netherlands0.7462121.00001D
14Brazil0.2581370.834133D
15Russian Federation0.0696471.00001C
16Switzerland1.000011.00001C
17Sweden0.839491.00001C
18Austria0.7431130.830434D
19Turkey0.3375271.00001C
20Norway1.000011.00001C
21Poland0.5168220.813035D
22Indonesia0.1895400.894127D
23Greece0.5743190.719642D
24Finland0.6992150.777938I
25South Africa0.4727250.721541C
26Ireland1.000011.00001C
27Portugal0.5362210.606346I
28Thailand0.1784420.681544D
29Iran1.000011.00001C
30Argentina0.4820231.00001C
31Malaysia0.3039340.801436I
32Czech Republic0.3341280.531548I
33Hungary0.3335290.699943I
34Egypt0.5630201.00001C
35Pakistan0.2114380.880329I
36Philippines0.3321301.00001I
37New Zealand0.4625260.942625I
38Columbia0.2926350.771939I
39Chile0.2814360.757040I
40Peru0.4730241.00001C
41Romania0.1478440.835232I
42Bangladesh1.000011.00001C
43Ukraine0.0442480.562447I
44Slovakia0.1883410.678945I
45Kazakhstan0.1065451.00001I
46Bulgaria0.1558431.00001I
47Lithuania0.2046391.00001I
48Uzbekistan0.0710461.00001I

Table 4.

TFEE of 48 countries

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4. A dynamic analysis of energy efficienciesof 30 Chinese provinces during 2000-2003

This section aims to investigate the total factor energy efficiency of main areas in china using the time-series data from 2000 to 2003. These areas shown in table 5 include 12 provinces in the east area, 10 provinces in the central area and 8 provinces in the west area. Consisting of fast-developing regions like Beijing, Shanghai, Guangdong etc., the east area owns GDP output around half of the country. The central area contains inland provinces such as Shanxi, Jilin, Henan etc. This area has a large population and tremendous potential. Compared with the other areas, the west area is the least developed region in China, containing provinces of Sichuan, Guizhou, Yunnan etc. In our study, Tibet, which is also a province in the west area, is missing due to the unavailability of data. Similar as the analysis in the above section, GDP is the only output and non-resource inputs are capital stock and labor while energy inputs are represented as crud oil, coal and electric power. The data on energy input are collected from China Energy Statistical Year Book (2004). GDP and labor data are collected from the Statistical Year Book of China published by National Bureau of Statistics during 2000-2003. The data on capital stock comes from Jun et al. [23].

AreasNum.Provinces
East area12Beijing, Tianjin, Hebei, Liaoning, Shanghai, Jiangsu, Zhejiang, Fujian, Shandong, Guangdong, Guangxi, Hainan
Central area10Shanxi, Inner Mongolia, Jilin, Heilongjiang, Anhui, Jiangxi, Henan, Hubei, Hunan, Chongqing
West area8Sichuan, Guizhou, Yunnan, Shaanxi, Gansu, Qinghai, Ningxia, Xinjiang

Table 5.

Chinese provinces in different areas

Curves in Figure 1 show the difference among the average TFEE scores of the provinces in the east, central and west areas using model (4). Obviously the east area is the most efficient and the west area is worst in any year. Meanwhile, it is shown that energy efficiencies for all areas are gradually improving. The detailed results are listed in Table 6. It can be easily observed from the table that most of efficient provinces are in the east area. TFEE scores of Liaoning, Shanghai, Jiangsu, Guangdong, Guangxi, Hainan, Fujian are all at a high level. Provinces in the central area are not as good as the provinces in the east area except Anhui which is adjacent to the east area. Another province in the central area, Shanxi, for specially, has very low TFEE scores during the four years and makes little progress. The situation in the west area is even worse other than Sichuan, Yunnan, Qinghai and Ningxia.

Figure 1.

TFEE of 30 provinces during 2000-2003

Table 7 is used to clarify which part makes the energy efficiency get improvement. During 2000 to 2001, the average value of Malmquist production index (MPI) for all provinces is 1.13 which means the efficiency in 2001 is better than 2000. Catch-up effect (CE) and frontier-shift effect (FE) are two parameters to distinguish which part is functioned. The data on the last row show that the average value of CE is 1.00 and FE is 1.13. That is to say, the technical efficiency in 2001 is almost the same as that in 2000, while the production frontier gets improvement during the two years. Improvement is also achieved in next two years, but there is something different that both CE and FE are working.

In order to compare the trends of 3 areas, we make a summary in table 8 using the average data. It is clear that the central area has the greatest achievement and the west area is following. FE is always doing better than CE.

No.ProvinceArea2000200120022003
1BeijingE0.86440.95570.96341.0000
2TianjinE0.99111.00001.00001.0000
3HebeiE0.77020.80280.78480.7663
4LiaoningE1.00001.00001.00001.0000
5ShanghaiE1.00001.00001.00001.0000
6JiangsuE1.00001.00001.00001.0000
7ZhejiangE0.99491.00001.00001.0000
8ShandongE1.00000.88360.99941.0000
9GuangdongE1.00001.00001.00001.0000
10GuangxiE1.00001.00001.00000.9406
11HainanE1.00001.00001.00001.0000
12FujianE1.00001.00001.00001.0000
13ShanxiC0.45100.44690.51500.5847
14Inner MC0.66640.69290.71940.8298
15JilinC0.66570.68260.68900.7548
16HeilongjiangC0.83230.77910.87950.9683
17AnhuiC1.00001.00001.00001.0000
18JiangxiC0.95080.98001.00001.0000
19HenanC0.90750.90440.89671.0000
20HubeiC1.00001.00000.90770.9541
21HunanC0.92840.93050.91380.9342
22ChongqingC1.00001.00001.00001.0000
23SichuanW1.00001.00001.00001.0000
24GuizhouW0.52580.52320.52030.6556
25YunnanW1.00001.00001.00001.0000
26ShaanxiW0.51910.53070.57010.6067
27GansuW0.42060.42290.41530.4126
28QinghaiW1.00001.00001.00001.0000
29NingxiaW1.00001.00001.00001.0000
30XinjiangW0.73560.74310.74970.8371

Table 6.

TFEE of 30 provinces during 2000-2003

No.Province2000-20012001-20022002-2003
CEFEMPICEFEMPICEFEMPI
1Beijing1.111.051.171.011.051.061.031.071.11
2Tianjin1.011.031.041.001.021.021.001.071.07
3Hebei1.041.161.200.981.131.110.981.111.09
4Liaoning1.001.041.041.001.001.001.001.091.09
5Shanghai1.001.161.161.001.141.141.001.191.19
6Jiangsu1.001.201.201.001.161.161.001.101.10
7Zhejiang1.001.081.081.001.091.091.001.131.13
8Shandong0.881.100.971.131.101.241.001.151.15
9Guangdong1.001.181.181.001.031.031.001.061.06
10Guangxi1.001.081.081.001.001.000.941.071.01
11Hainan1.000.230.231.001.011.011.000.720.72
12Fujian1.001.081.081.001.101.101.001.071.07
13Shanxi0.991.041.031.161.061.231.141.051.19
14Inner M1.041.041.081.041.121.161.151.041.20
15Jilin1.031.011.041.011.021.031.100.981.08
16Heilongjiang0.941.010.951.130.981.111.100.961.05
17Anhui1.001.061.061.001.031.031.001.071.07
18Jiangxi1.031.001.031.021.001.021.000.960.96
19Henan1.001.161.160.991.141.131.114.194.65
20Hubei1.001.021.020.911.030.941.050.991.04
21Hunan1.001.001.000.980.980.961.020.960.98
22Chongqing1.003.583.581.003.823.821.004.274.27
23Sichuan1.001.531.531.001.681.681.001.591.59
24Guizhou1.000.950.950.991.021.011.260.821.04
25Yunnan1.001.091.091.001.121.121.001.161.16
26Shaanxi1.021.001.021.070.991.061.060.961.02
27Gansu1.001.021.020.981.031.010.991.041.03
28Qinghai1.000.940.941.000.940.941.000.940.94
29Ningxia1.000.910.911.000.910.911.000.900.90
30Xinjiang1.011.011.021.011.011.021.120.971.09
Average1.001.131.131.011.161.171.041.261.30

Table 7.

Changes of 30 provinces during 2000-2003

Areas2000-20012001-20022002-2003
CEFEMPICEFEMPICEFEMPI
East area1.001.031.041.021.071.091.011.071.08
Central area1.001.321.321.011.351.361.061.711.81
West area1.001.061.061.011.091.091.051.051.10

Table 8.

Average data of areas during 2000-2003

It is interesting to investigate the individual province. Here are some examples. First, we make a comparison between Shanghai and Hainan both of which are efficient during the periods. However, detailed data indicate that Shanghai keeps making frontier forward gradually while Hainan are opposite except year 2002. This could be explained by that the location of Hainan on the frontier is on the edge. Second, take Beijing for example. Beijing is non-efficient from 2000 to 2002 and finally becomes efficient at 2003 by making efforts on improving technical efficiency and putting frontier forward. Third, energy efficiency of Shandong province suffers a decline and is back to the normal level later. MPI during first period is decreasing mainly caused by declining CE. In the next two years, some parameters get recovery which makes MPI increasing.

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5. Conclusion

This chapter reviews the development process of the evaluation technique of energy efficiency and focuses on introducing the concept of energy intensity. However, missing the structure of energy consumption causes the energy efficiency estimated inaccurately. Thus, the current chapter introduces a weighed energy efficiency model based on DEA to fix it. Energy cannot produce production without non-energy inputs such as labor and capital. That’s why we extend the method to the total factor energy efficiency model. Energy efficiency of China and other 47 countries in 2003 are employed to illustrate the models. Results show that unbalance of energy efficiency exists. For china, specially, it needs to adjust energy consumption structure as its poor energy efficiency and improve GDP since its total factor energy efficiency is at a lower level than some developed countries.

As a key part, the chapter adopts Malmquist production index technique to analyze the dynamic change in energy efficiency of Chinese provinces which can further explore the reason for the variation of energy efficiency deeply. The chapter uses the proposed models to investigate the changes in energy efficiency of provinces in china during the period of 2000 to 2003. We find that the east area has better energy efficiency than the central and west area but lower improving rapid. In addition, it is interesting to find that energy efficiency of most provinces improves due to the extending frontier. Although our work mainly focuses on estimating energy efficiency at the macro-level, it can provide guidance to managers and manufacturers at the micro level.

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Acknowledgement

We would like to thank the financial support by Program for New Century Excellent Talents in University, Ministry of Education of China and National Natural Science Foundation of China (Grant No. 70801056, 71121061, 71090401/71090400 and 71110107024).

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Written By

Chenchen Yang, Feng Yang, Liang Liang and Xiping Xu

Submitted: 07 December 2011 Published: 17 October 2012