Abstract
China is currently facing water scarcity issues, which can partially be relieved with improvements in efficiency in its urban water supply sector. Using a manually collected utility-level dataset for 2009–13, we examine the performance of Chinese urban water utilities, taking into account their regulatory environment. Our main findings are that: (1) an increase in the number of non-technical staff does not increase output levels, while an increase in the number of technical staff, length of pipe or electricity usage can increase output; (2) customer density and non-household user rates are associated with lower levels of inefficiency (or higher levels of measured efficiency), while outsourcing staff rate, non-revenue water rate, and average piped water pressure do not significantly affect efficiency. These results suggest that Chinese urban water utilities can be improved through performance-based regulation and incentives that take into account environmental factors of utilities.
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1 Introduction
China is currently facing several obstacles in its water supply sector. Years of fast paced industrial growth have led to an increase in standard of living for the population, but the rapid pace of urbanization and industrialization has also been accompanied by over-exploitation of water sources, reducing water resource availability. The average per capita endowment of water in China is approximately 2000 m3 annually, compared to a global average of about 6200 m3 (World Bank 2012). By 2011, China’s urban population had reached more than 50 % of the total population, but 400 out of 669 cities faced water shortages and 108 had severe water shortage problems. This translates to an urban population of 160 million that is affected by water shortages (Xinhua net 2014).
China’s water shortage problems are so substantial compared to its natural endowment, that they cannot be managed solely through the exploitation of new sources (Liu and Speed 2009). Several supply and demand side approaches, such as inter-basin transfers, desalinization, and waste water reclamation, and conservation, can be used to address water scarcity in the long term (Cheng and Hu 2012). A cheaper, more immediate, and complementary solution consists of increasing production efficiency at the water utility level. Thus, identifying characteristics of the Chinese water utility sector that are associated with increases in efficiency is of vital importance.
The purpose of this paper is to examine the effect of the regulatory environment on Chinese urban water utility firms and to encourage efficiency improvements. The regulatory environment here is defined as the set of rules and regulations governing the urban water sector, including pricing, investment, employment, pipe maintenance and consumer type. These can be reflected in the exogenous factors that interfere in the operational performance of urban water utilities. In this study, we show that data driven efficiency studies can provide clues as to how Chinese policy-makers can focus their effort on addressing water scarcity.
The remainder of this paper is organized as follows. Section 2 describes the background of the Chinese urban water utility sector with a focus on its regulatory environment. Section 3 reviews the water efficiency literature, incorporating environmental factors. Section 4 explains the methodology adopted. In Section 5, we present the efficiency estimation result. Finally, Section 6 concludes.
2 Background: Chinese Water Utility Sector
2.1 Institutional Characteristics
China’s urban water services are mainly provided by water supply companies. Most urban water utilities are state owned, but there is some private participation (Wang et al. 2011). In 2010, China had average water coverage of 90.3 % of the urban population; 15 out of 34 provincial-level administrative divisions had coverage above this average (The Ministry of Housing and Urban–rural Development of the People's Republic of China 2012).
Water prices in China only cover the utilities’ operational costs, and are far from covering investment and wastewater treatment costs (Yin et al. 2008). Underpricing in China’s water sector is one of the major causes for allocative inefficiency (World Bank 2007). Utilities may lack the cash flows for appropriate network maintenance, rehabilitation, and replacement. According to Jiang (2009) current household expenditures for water in China account for roughly 1.2 % of disposable income, compared to 4 % in developed countries. For this reason, current reform efforts are centered on changing pricing mechanisms so that they better align with full cost recovery (Zhong and Mol 2010), but progress raising water prices has been slow because of concerns about access to water being a human right (Jiang 2009), concerns about limiting access for the poor, and concerns about negative impacts on the local economies (Lee 2006).Footnote 1
Following the pace of urbanization and industrialization, China’s urban water billing system has been upgraded from in-person to automatic billing. Water bills, which are determined by each user’s water meter data, are charged directly to customers’ bank accounts. Under strict government regulations, this automatic billing system and low water prices contribute to a relatively high urban water billed rate in China.
It should be noted that water utilities did not become as market-oriented as other industries during the Chinese economic reform, leading to regulated low prices and government intervention. Urban water utilities highly depend on subsidies from the national and local governments to cover their costs. Their motivations to improve efficiency are not driven by profit margins, but depend on governmental administration and supervision—where local decision-makers have relatively short time-horizons.
2.2 Regulatory Environment
Water administration is the responsibility of the Ministry of Water Resources, a Chinese government department that was founded in 1949. Its main functions include: providing draft legislation, promulgating water administrative rules and regulations, planning national water investment and fiscal subsidies, and supervising local governments’ activities in the water sector. Due to the complexity of local natural resources (hydrology, topology, distance from sources, and environmental/ecological conditions) and the economic situation (especially industry mix and income levels), the Ministry of Water Resources is not directly involved with the local water administration, and instead assigns the duty of water production and delivery to local governments. However, at the city level, water administration involves multiple departments, including the Environmental Department, the Commerce Department and the Housing Department. Local water administration suffers from a lack of policy coherence, reflected in communication problems, lack of clarity in regulatory roles and responsibilities, and the duplication of functions among different departments.
The current method for managing water stems from the 1988 Water Law, which was passed during China’s planned-to-market economy transition (Liang 2005). Today, laws and policies are directed by the central government, with some negotiation between local and central authorities (Speed 2009). This has led to some ambiguities over system ownership and maintenance responsibilities (Cheng and Hu’ 2012). The Water Law was amended in 2002 with the goal of addressing some of the earlier law’s shortcomings. One of the four main topics included in the new Water Law is water efficiency and conservation (The National People’s Congress of the People's Republic of China 2002). Lee (2006) contends that competition and conflicts of interest among various government agencies can occur, and that one of the main problems in the regulatory arena stems from fragmented policy-making and implementation.
In addition to a lack of policy coherence related to ambiguities over system and governance responsibilities, there are currently no mechanisms in place to incentivize performance enhancing measures at the utility level.Footnote 2 A possible future avenue for the Chinese urban water utility system to increase efficiency could be the introduction of performance-based regulation (PBR). PBR provides utilities with strong incentives to reduce costs through rate-setting mechanisms that link rewards to desired targets by setting rates according to external indices (Berg 2013). Chinese water data are available at the province and city level, but are very limited at the utility level. This lack of transparency limits the potential for detailed performance evaluations of city water utilities. Thus, it important to improve the collection, authentication, and sharing of information; this would enhance performance analyses, leading to realistic targets and improved incentive mechanisms.
3 Water Efficiency Literature Incorporating Environmental Variables
Water utility efficiency studies focus on examining the following objectives: scale, scope, and density of utilities, type of ownership (private versus public), regulation, and benchmarking. Berg and Marques (2011) provide a literature survey of 190 quantitative studies of water utilities. Most studies examine water utilities in Europe and North America, and use cost or production functions.
In recent years, several benchmarking studies have highlighted the importance of incorporating environmental variables that are expected to influence performance. These studies measure technical efficiency using cost or production functions, and either Data Envelopment Analysis (DEA) or Stochastic Frontier Analysis (SFA) techniques. DEA, a non-parametric method, uses linear programming to determine the efficiency of firms. Water utility production function DEA studies generally employ an input orientation, in which inputs are minimized for a given output level. SFA, a parametric method, uses statistical analysis to examine efficiency. Unlike ordinary least squares methods, SFA models assume that the error term is composed of both noise and productive inefficiency. There are advantages and disadvantages to both DEA and SFA and neither method is strictly preferred over the other.Footnote 3
Recent studies have been more comprehensive—incorporating factors beyond management’s control. Carvalho and Marques (2011, 2016) study the efficiency of Portuguese water utility companies using DEA techniques and argue that excluding environmental variables in efficiency studies could result in biased estimates. In a similar study, Marques et al. (2014) examine the influence of environmental factors on Japanese water utilities using a DEA production function. They include several exogenous environmental variables such as outsourcing, leakage, and peak factor. Picazo-Tadeo et al. (2009) study Spanish water utilities with a focus on differences between private and public firms. Byrnes et al. (2010) examine the efficiency of 52 water utilities over a 4-year period in Australia, using a production function DEA model that incorporates exogenous environmental variables such as residential consumption (capturing customer mix) and customer density. Renzetti and Dupont (2009) study the influence of environmental variables such as population density in a cross-section of Canadian water utilities. Correia and Marques (2011) apply a SFA benchmarking method to explore how ownership, size, diversification and vertical integration relate to efficiency. Phillips (2013) examines the efficiency of water utility firms in Japan, using a SFA production function. This study’s environmental variables include customer density, outsourcing, and intake water volume. Mugisha (2014) examines technical efficiency effects in Uganda’s water utilities for the 2002–2010 period and finds that financial incentives and increased service coverage improve efficiency, while targets such as the reduction of non-revenue water reduce it. Buafua (2015) studies technical efficiency of urban utilities in sub-Saharan Africa, and finds that regulating operators using performance contracts and private sector participation leads to higher efficiency.
Although the literature examining water efficiency in developed countries is extensive, data driven efficiency studies of Chinese water utilities are limited, and use data from before 2009. To our knowledge, there are only four empirical economic studies in this field. Jiang and Zheng (2014) study the impact of private sector participation (PSP) on Chinese water utility performance, using a panel of 208 utilities from 1998 to 2007. They find that PSP is weakly associated with increases in total factor productivity (TFP).Footnote 4 Wang et al. (2011) also study the impact of private sector participation in China’s urban water system, using panel data from 35 major cities in the 1998–2008 period. They find that introducing private sector participation is correlated with improvements in integrated production capacity and water coverage rates. Regarding performance, they find that private participation by foreign companies increases performance. Neither of these studies are benchmarking studies; they do not focus on the efficiency of China’s water utilities or the role of environmental factors.
Browder et al. (2007) provide a very general overview of the performance of Chinese urban water utilities, which have very unequal levels of performance. They also provide a very general performance assessment, examining one variable at a time and providing summary statistics.
Ma et al. (2016) study water utilization efficiency in China. The authors use sewerage discharge and provincial GDP as output and economic growth, industrial structure, technological progress, government influence, economic openness, water endowment, and water prices as inputs. Their main findings suggest that (1) regions with higher economic growth are associated with better utilization efficiency, (2) areas with heavy agricultural use have lower utilization efficiency, (3) and technological progress is associated with better utilization efficiency. The main difference between our papers is on the focus: Ma et al. (2016) look at the entire water endowment resource and see how efficiently water as a resource is used in China’s provinces. Our study looks how water is efficiently delivered from urban water utilities to its final customers (households, commercial, industry, and government).
There are very few studies of Chinese urban water supply performance that use statistical methods, mainly due to data availability. China’s Urban Water Association, a nonprofit national organization, has started to collect performance data at the utility level. This enables us to evaluate China’s urban water utility performance, incorporating environmental factors to address the reasons for inefficiency in the sector.
4 Model
SFA models were simultaneously introduced by Aigner et al. (1977) and Meeusen and Van den Broeck (1977). We use a SFA model specified by Battese and Coelli (1995) to examine the performance and operational variables influencing Chinese water utility firms, which include both noise and an additional component representing productive inefficiency in the model’s error term. This is done through a one-step approach in which both the stochastic and efficiency components are estimated simultaneously (Schmidt and Wang 2002). Efficiency is defined as the output of a given firm relative to the output that could be produced by a fully efficient firm using the same input; water utility’s efficiency is affected by its regulation environment.
4.1 Data Description
We manually collected data from the Chinese Yearbook of Urban Water Supply from 2010 to 2014. The yearbook publishes performance data at three different levels: province, city and utility. We use a pooled unbalanced panel sample consisting of 59 city utilities (140 observations) between 2009 and 2013. The performance data is self-reported by city utilities and collected by China’s Urban Water Association. The model considers one output, four inputs and five environmental variables (also known as the inefficiency factors of the model).
4.2 Production Function Model Description
Consider a Cobb Douglas stochastic frontier production function one-step inefficiency effects model as specified by Battese and Coelli (1995) for panel data:
where β is a vector of unknown parameters to be estimated; lnYit is the natural logarithm (with base e) of total delivered water volume in a year in 10,000 m3(output), for the ith utility in year t where i = 1,…, I and t = 1, …, T; inputs are defined as: Capital (Kit), proxied as length of pipes (in 1000 m); labor (LTit and LNTit) measured by the number of technical staff and non-technical staff, respectively; and energy (Eit), hourly electricity usage (100,000 kwh).Footnote 5 Vit is an error term picking up what the model cannot explain (noise); and Uit is a technical inefficiency term, consisting of non-negative random variables. The Uit term is subtracted because inefficiency results in less output. Vit is assumed to be independent and identically distributed with N(0,σ2) random errors, which are distributed independently from Uit. Uit is assumed to be independently distributed, and obtained by truncation at zero of the normal distribution with mean Zitσ and variance σ2, where Zit is a vector of explanatory variables associated with technical inefficiency of production for utility firms over time.
The relationship between Uit and Zit is defined by the following technical inefficiency effects specification:
where δ is an unknown vector of coefficients to be estimated; Wit is a random variable defined by the truncation of the normal distribution with mean 0 and variance σ2 (Coelli 1996; Battese and Coelli 1995). The environmental variables that are expected to influence performance are defined as: Outsourcing ratio (routit), measured by the ratio of number of staff based on temporary contracts to the number of total staff (%); Customer density (cusdenit), defined by the number of customers per length pipe (persons/1000 m); Nonrevenue water rate (nonrevrit), defined by the ratio of volume of nonrevenue water to the number of total delivered water volume (%); Non-household user rate (nonhhdr), defined by the ratio of the number of non-household users to the number of total water users; and average piped water pressure (avepressit) (1 million pa).The use of these variables in the inefficiency effects model allows us to incorporate variables that affect the efficiency of water utilities in China. Summary statistics for variables in the stochastic frontier production function are given in Table 1.
The model is estimated using the maximum likelihood method. The parameters in the stochastic production frontier (Eq. 1) and the technical inefficiency effects (Eq. 2) are estimated simultaneously. The technical efficiency of production obtained for the ith utility firm at year t, is always between 0 and 1 measuring the output of the ith utility firm relative to the output that could be produced by a fully efficient utility firm using the same input vector. It is defined by Eq. 3 below and automatically calculated by Coelli’s (1996) FRONTIER version 4.1 software.
By definition, firms with a technical efficiency score closer to 1 are more efficient.
In stochastic frontier models, the composite error is given by Vit – Uit. If the Uit part of the equation is not necessary, OLS would provide consistent estimates. In order to test for whether or not stochastic frontier analysis is needed, a value for gamma is calculated by Battese and Coelli’s (1995) model, where gamma is defined as \( \gamma =\raisebox{1ex}{${\sigma}_u^2$}\!\left/ \!\raisebox{-1ex}{${\sigma}^2$}\right. \) and ranges from 0 to 1. A gamma value of 0 indicates that OLS provides consistent estimates and there is no need for an inefficiency component in the error term. Our estimate for gamma is 0.45 (t-ratio 2.94). Since gamma is statistically significant at the 1 % level, at least some variation of the composite error term is due to inefficiency, implying that SFA is preferable to OLS in this context.
5 Empirical Estimation
5.1 Results
The efficiency of Chinese firms in our sample ranged from 0.12 (least efficient) to 1.00 (most efficient). This means that the most inefficient firm could reduce usage of inputs by 88 %. The frequency distribution of technical efficiency scores can be seen in Fig. 1. Over 80 % of the firms have an efficiency score of less than 0.70 (see Fig. 1). These results are consistent with previous work suggesting that performance of Chinese water utilities is unevenly distributed (Browder et al. 2007); the results indicate that there are opportunities for weak performers to learn from strong performers.
The results for the production function and inefficiency effects are presented in Table 2. All of the input variables are positive, as expected, implying that increases in inputs lead to increases in output. A 1 % increase in technical staff, for example, is associated with a 0.22 % increase in total delivered water volume (see Table 2). All inputs, with the exception of non-technical staff are statistically significant at conventional levels. The non-statistically significant result for the non-technical staff variable may be related to the issue of overstaffing. According to Nitikin et al. (2012), overstaffing is a well-known problem for the public water sector in China. This problem is not currently being addressed aggressively due to concerns about the welfare implications of laying off the excess labor force. This result is also consistent with how employment downsizing is seen as one of the major benefits of utilities that have been privatized, as noted by Jiang and Zheng (2014).
As mentioned earlier, given China’s current strategic shift towards policy implementation that includes improvements in water use efficiency at the water utility level, it is useful to identify environmental factors that influence performance.
The customer density variable has a negative coefficient that is statistically significant at the 1 % level (see Table 2). According to our results, water utilities with greater customer density tend to be less inefficient (more efficient). This result is expected because, assuming a fixed network length, adding more customers translates into higher levels of output, given fixed input levels. It also suggests that increasing migration from rural to urban areas may be beneficial to China’s current urban water system if urban sprawl is avoided. In China, water scarcity and pollution are problematic in both rural and urban areas. Given the non-point nature of rural polluters, it has been noted that achieving efficient use of rural water would require more serious coordination and enforcement costs than achieving efficiency in urban areas (Nitikin et al. 2012).Footnote 6
Our customer density finding is consistent with the water utility efficiency literature, which supports the existence of economies of density in Italy and Spain (Antoniolli and Filippini 2001; Picazo-Tadeo et al. 2009 Footnote 7). For Asian countries, the only studies we are aware of that examine economies of density are of Japanese water utilities, presumably due to data availability. Mizutani and Urakami (2001) examine network length in the context of a Seemingly Unrelated Regression (SUR) cost model, and show economies of network density for water utilities in Japan. Phillips (2013) also studies Japanese water utilities and finds that water utilities with greater customer density are associated with less inefficiency. Thus, our results are consistent with recent studies of Asian water utilities.
The non-household rate variable has a negative coefficient (see Table 2). This implies that water utilities with a larger customer base of non-households (i.e., more industrial and commercial customers) tend to be less inefficient, suggesting that there are efficiencies involved in serving industry, businesses, and government when compared to residential customers. Water utilities with more residential customers are expected to have higher costs, which are related to lower efficiency levels.Footnote 8 This is expected given how non-residential customers have more predictable patterns of use. This result is consistent with Anwandter and Ozuna (2002) who studied the efficiency of water utilities in Mexico and found that utilities serving a higher proportion of non-residential customers were more efficient.
The outsourcing ratio, non-revenue water rate, and average piped water pressure variables are not statistically significant at conventional levels, implying that there is no effect on inefficiency for the data in our sample (see Table 2). In China, the employment contract between outsourcing and internal staff is usually quite different from other countries: outsourcing staff have obvious disadvantages in terms of insurance, pensions, and salary. Additionally, outsourcing staff’s contracts are temporary, while internal staff’s contracts are permanent. As a result, on the one hand, outsourcing staff have less incentives to work hard given their low income packages and short-term employment contracts; on the other hand, internal staff also have less incentives to improve their performance because poor performance rarely results in layoffs, given their permanent contracts. This negative effect of outsourcing ratio on production efficiency is (presumably) countervailed by the negative effect of the internal staff ratio, so our results show that the outsourcing ratio has insignificant effects on inefficiency.
Regarding non-revenue water, compared to other middle income countries, such as Russia and Brazil, China has more compact systems with 1100 people per kilometer of distribution network on average (Browder et al. 2007). For this reason, non-revenue water percentages are much lower than in other countries which may help explain our findings for this variable.Footnote 9 In addition, Chinese cities have high billing and collection rates due to their automatic billing systems—reducing unpaid bills.
To understand the result of average piped water pressure from Table 2, context should be taken into account. China’s landscapes vary significantly across its vast width, resulting in unevenly distributed pressure. Although higher piped water pressure generally drives low water leakages, thus being positively related to efficiency in theory, China’s diverse landscape causes the variation of water pressure instead of the average to affect production efficiency of water utilities. Thus, the nature of China’s landscapes may provide an explanation for the insignificant estimation of the average piped water pressure variable.Footnote 10
5.2 Institutional Discussion
The main purpose of this section is to utilize the efficiency scores derived for each firm in our model from section 5.1 to study how location (region) and labor related to firms’ efficiency. Given the lack of utility-level performance data, most studies of Chinese urban water institutions are qualitative. To fill this research gap, our empirical efficiency study can shed a light on how two important institutional characteristics (region and ratio of number of staff to number of customers) relate to Chinese urban water efficiency quantitatively.
China exercises jurisdiction over 22 provinces, 5 autonomous regions, 4 direct-controlled municipalities (Beijing, Tianjin, Shanghai and Chongqing), and 2 mostly self-governing special administrative regions (Hong Kong and Macau). This study involves the main urban utilities of 9 provinces and 3 direct-controlled municipalities. It was expected that poor raw water conditions would require more input to produce the same levels of output. The main rivers that flow through China include the Yangtze River, the Pearl River, the Yellow River, the Huai River, the Hai River, the Liao River and the Songhua River. Among them, the raw waters from the Yangtze River and the Pearl River are of high-quality, while the raw water from the Huai River and the Hai River are of low-quality (The Ministry of Water Resource of the People's Republic of China 2015). Figure 2a shows that urban water utilities in Guangdong (along the Pearl River) and Shanghai (along the Yangtze River) have relatively high efficiency scores, while urban water utilities in Liaoning (along the Liao River) have relatively low efficiency scores. In addition, Guangdong and Shanghai are the most developed regions in China, and generally show high efficiency in operation and production, regardless of the industry.
As Fig. 2b indicates, the ratio of number of staff to number of customers shows a weak negative relationship with efficiency scores. A few utilities with low efficiency scores show high ratio of staff to customers. The labor supply of these utilities has a high percentage of nontechnical staff. According to our SFA result, as an input variable, the number of nontechnical staff has no significant effect on increasing output. Thus, utilities with low efficiency do not significantly show that they need more labor input to supply water customers. This result is consistent with privatization studies suggesting that gains from privatization seem to stem from reductions in the labor force.
5.3 Alternative Models
Efficiency in producing outputs using inputs can also be measured using an SFA model that does not include controls for the regulatory environment in the inefficiency term and a DEA model. We first tested our model against a different SFA model to check for the sensitivity of parameter estimation in the production function. It is important to note, however, that our additional specification does not account for the regulatory environment and thus, does not include inefficiency factor that are provided by the variables in Table 2. Table 3 includes the main results from our new production function model. If we compare this model to the results from Table 2, we can see that once again, all inputs are positively related to the output. The main difference is that non-technical staff is now statistically significant.
Another method commonly used for modeling efficiency is DEA. This non-parametric method and SFA are not directly comparable, because DEA does not provide parameters. However, DEA does provide efficiency scores, so we can compare these two methods according to estimated efficiency scores. We ranked the firms in our sample for the year 2012 (the year with the most observations) using the efficiency scores obtained from each model and created scatter plots to compare the rankings of each new model to the ranking provided by our preferred specification presented in section 5.1, as shown in Fig. 3. We added a trend line that shows an expected positive relationship between the rankings. The graphs suggest that even though DEA and SFA are completely different models that cannot be directly compared to each other, there is some agreement as to which firms are efficient for our Chinese dataset (if the rankings were very closely related, the data would be at the 45 degree line).
6 Concluding Observations
In this study, we study the performance of Chinese urban water utilities, incorporating their regulatory environment. The estimation shows that the efficiency of Chinese firms in our sample ranges from 0.12 (least efficient) to 1.00 (most efficient). Since a high level of inefficiency exists, there is an opportunity to improve Chinese urban water utilities by providing a regulatory framework that incorporates performance benchmarking. We also find that an increase in the number of non-technical staff does not raise the output level, measured by delivered water volume per year, while an increase in the number of other inputs (technical staff, length of pipe and electricity usage) can improve the output levels. According to our results, environmental factors, such as customer density and the non-household user rate, are associated with lower levels of inefficiency. At the same time, the outsourcing staff rate, non-revenue water rate, and average piped water pressure variables were not found to be significantly related to efficiency.
To the best of our knowledge, this is the first quantitative study of the influence of the regulatory environment of urban water utilities in China. China’s economic development has achieved great success thanks to rapid urbanization, but its water scarcity problems could obstruct further development. Water issues have driven several recent policy changes and are expected to drive even more changes in the future. One such policy change could come from the way in which urban water utility firms are regulated. If China moves to regulation that takes into account performance, it would be important to consider its environmental factors, so as to make fair comparisons among utilities. Moreover, this regulatory framework could increase China’s policy-makers’ awareness of possible changes to the operational environment of water utilities that can be made to promote utilities’ performance.
Notes
Nevertheless, there have been examples of water prices being raised in urban areas such as Beijing (Lee 2006).
Mugisha (2007) provides examples of how incentives have been applied to water utilities in Uganda.
The main advantage of SFA compared to DEA is that it accounts for statistical noise and allows for statistical inference. The main advantage of DEA compared to SFA is that it does not require the imposition of a functional form and can incorporate multiple outputs relatively easily (Coelli et al. 2005).
Most of these results are not statistically significant at conventional levels.
Electricity is an input for pumping and distributing water. We lack data on chemicals for water treatment and distance from water source.
Rural migration to urban areas is, of course, accompanied by consequences in several other areas, such as air quality, overall level of industrialization, etc.
This variable influences costs rather than efficiency. Even though these are not the same concept, this variable has been included both in this study and in other production function studies in the literature because excluding it is expected to result in a biased analysis since it is an influential environmental variable. Ignoring this variable is expected to result in unfair comparisons of efficiency where firms with higher proportions of residential customers would receive lower efficiency scores (Carvalho and Marques 2011).
Note that leakage per kilometer can still be high, so further research in this area is needed to see whether performance improvements can be achieved by repairing or replacing pipes.
Without the water pressure variation data, this paper cannot provide direct evidence of how the variation affects efficiency. This is an area for future research.
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Acknowledgments
We are thankful to Sanford Berg and Rui Cunha Marques for their advices and suggestions. We also thank Teng Huang for helping us collect the data. Financial support from the Department of Education of Guangdong Province, China (Funding No.: 2015WQNCX127) and financial support from Shenzhen University, China (Funding No.: CCSEZR1613 and 15QNFC38) are also gratefully acknowledged. All remaining errors are our own.
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Li, F., Phillips, M.A. The Influence of the Regulatory Environment on Chinese Urban Water Utilities. Water Resour Manage 31, 205–218 (2017). https://doi.org/10.1007/s11269-016-1519-z
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DOI: https://doi.org/10.1007/s11269-016-1519-z