Next Article in Journal
Analysis of the Tourism Demand for Iberian Ham Routes in Andalusia (Southern Spain): Tourist Profile
Next Article in Special Issue
Indicators and Assessment System for Sustainability of Municipalities: A Case Study of South Korea’s Assessment of Sustainability of Cities (ASC)
Previous Article in Journal
Environmental vs. Social Responsibility in the Firm. Evidence from Italy
Previous Article in Special Issue
Landscape-Based Assessment of Urban Resilience and Its Evolution: A Case Study of the Central City of Shenyang
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Housing Indicators for Sustainable Cities in Middle-Income Countries through the Residential Urban Environment Recognized Using Single-Family Housing Rating Systems

by
Héctor Saldaña-Márquez
1,
Diana C. Gámez-García
1,
José M. Gómez-Soberón
2,*,
Susana P. Arredondo-Rea
3,
Ramón Corral-Higuera
3 and
María C. Gómez-Soberón
4
1
Barcelona School of Architecture, Polytechnic University of Catalonia, 649 Diagonal Avenue, 08028 Barcelona, Spain
2
Barcelona School of Building Construction, Polytechnic University of Catalonia, 44-50 Doctor Marañón Avenue, 08028 Barcelona, Spain
3
Mochis Faculty of Engineering, Autonomous University of Sinaloa, no number Fuente de Poseidón y Ángel Flores, 81210 Los Mochis, Mexico
4
Civil Engineering School, Metropolitan Autonomous University. Av. San Pablo 180, 02200 Mexico City, Mexico
*
Author to whom correspondence should be addressed.
Sustainability 2019, 11(16), 4276; https://doi.org/10.3390/su11164276
Submission received: 9 July 2019 / Revised: 27 July 2019 / Accepted: 30 July 2019 / Published: 7 August 2019

Abstract

:
This study presents a comparative analysis of the housing indicators used by the single-family housing rating systems (SHRSs), in which the residential urban environment (RUE) influences buildings’ certification scores, emphasizing the relationships of six systems developed by middle-income countries (MICs)—BEST, CASA, GBI, BERDE, Green Homes, and LOTUS—and the two most-recognized rating systems, BREEAM and LEED. The aim is to provide new housing indicators that are capable of bringing the concept of sustainability into the cities of MICs. The results reveal that the percentage of influence that single-family housing (SFH) can achieve in the metric established by each system is relatively low. However, considering all of the identified indicators, this influence could increase to 53.16% of the total score in multi-criteria evaluations. Furthermore, a significant lack of indicators for mandatory criteria evaluations was found, with CASA being the only system that considers their inclusion. This paper identifies 37 indicators for multi-criteria assessments and two for mandatory-criteria assessments, providing new perspectives on several topics. Furthermore, the methodology established to obtain the indicators could be useful for other researchers in the identification of new sustainable indicators.

Graphical Abstract

1. Introduction

1.1. Background and Research Objectives

According to recent estimates, the planet will be populated by over 8.5 billion people in 2030 [1]. Considering the enormous impact of human activity, e.g., climate change and environmental destruction [2,3,4], as well as the constant trend toward urbanization [5,6], the unavoidable truth is that humanity must face up to the challenge of creating livable and sustainable urban habitats while maintaining and developing cities [7,8,9].
Housing indicators are resources that make it possible to study the issues and conditions of human settlements, as well as providing the basis for their monitoring [10]. They are also considered as useful resources to help in promulgating sustainable political decisions [6]. It is important to consider these indicators during the planning process of cities because the qualities of residential urban environments (RUEs) can seriously affect their livability [11,12,13,14,15].
Several researchers have recently applied housing indicators in order to achieve or enhance sustainability [16,17,18,19,20,21,22,23]; some of these investigations refer to social housing [17,18,21,22]. Among the indicators that were analyzed are those referring to household vulnerability; these studies found that social housing tends to be inhabited by people with below-average incomes [18,21] who are vulnerable to energy poverty. To solve this issue, Llera-Sastresa proposed a methodological approach based on indicators that improves energy management in social housing [21]. In this sense, Monzón et al. [17] developed a system of indicators to detect multifamily dwellings that have weak energy, acoustic, and accessibility performance. Similarly, Morganti et al. [20] proposed an indicator called building mass, which may contribute to the reduction of energy demand. Other works have proposed social and economic indicators that can help to predict the origin of mortgages as well as housing prices [16]. On the other hand, some researchers have studied indicators for green housing [19,23]. Among these, the most recognized global rating systems (BREEAM, LEED, GBTool, CASBEE) and their implications on sustainability indicators have been evaluated [23].
The relevance of the study of the indicators recognized by rating systems is that these systems, among the plethora of existing instruments used to evaluate building sustainability, have become commonly used in the building industry [24,25,26,27,28]. The flexible framework of these methods makes them receptive to covering more sustainability aspects [29], connecting the neighborhood and community, and thus contextualizing them on a broader scale [30]. One of the virtues of rating systems is their ability to evaluate a wide variety of different indicators as a whole, even though these might have different units of measurement [31]. This makes them a unique method by which to obtain indicators that have been proven in the construction sector in different regions around the world, and which in turn, have the support of experts who have participated in the development of each of the systems.
The comparison of the level of the indicators in rating systems comprises a minor part of the studies carried out in the academic field using a comparative approach [32]. However, this level of detail is recommended to obtain results for a specific aspect [32]. In contrast to other studies that focus on the level of the indicators [33,34,35,36,37], this work has centered on the initial situation of RUEs during the SHRS criteria scoring process. The significance of focusing on the study and acquisition of indicators has been shown in several publications, in which it is argued that the success of any evaluation process depends mostly on the indicators used [31,38,39,40,41].
The primary aim of this paper is to identify single-family housing indicators concerning RUE characteristics (SHIRUEs), recognized as green, ecological, or sustainable by the single-family housing rating systems (SHRSs). The objective is that these indicators will be of use to those in charge of configuring RUEs in the pursuit of safer, more inclusive, resilient, and sustainable human settlements in middle-income countries (MICs).
In parallel with the primary aim, it is expected that this study will provide a picture of the current situation in which the SHRSs of MICs consider the impact that RUEs have on a home’s classification as green, ecological, or sustainable. Moreover, although the findings are directed toward obtaining useful indicators for MICs, the discussion of the results provides new perspectives about different topics. This may prove helpful for others involved in the development of a SHRS, as well as in carrying out policies related to the residential sector and to single-family housing (SFH).

1.2. Why Address Single-Family Housing of the Middle-Income Countries through the Residential Urban Environment?

In the United Nations Conference on Housing and Sustainable Urban Development (UN-Habitat III), held in Ecuador in October 2016, it was pointed out that “housing has not been appropriately integrated into urban policies in spite of residential land use occupying between 65 and 75 percent of the surface of a city.” [42]. This situation is most evident in the MICs, in which the need for the prioritization of these issues has been established in several previous studies [43,44,45,46,47,48].
One of the main causes of the lack of integration between housing and the RUE is that priority has been given to the search for efficient buildings, instead of providing an environment that integrates both elements [49,50]. This, by analyzing the relationship between the building and the qualities of its immediate environment, can provide strategies to achieve energy efficiency, mitigate greenhouse gases, and improve adaptation to climate change in cities [24,51,52].
Single-family housing (SFH) is the most representative housing type in the MICs and has the most significant environmental impact [53,54,55]. Furthermore, most housing stock financing is still dedicated to it [56]. According to the World Bank, more than half of the places that will be urbanized by 2030 have not yet been built [57]; it is expected that a significant number of these constructions will be in the MICs [58]. Therefore, the characteristics and configurations that these countries establish as intrinsic to defining sustainable housing (green or ecological housing) will have a decisive impact on the cities since more than 65% of their surface corresponds to the residential sector [42].
Research, such as that of Papargyropoulou et al. [59], suggest that the use of rating systems should be a mandatory requirement in the planning process of the buildings in the MICs. Nevertheless, the findings of this study reveal an urgent need to either redesign the weighting of the SHIRUEs used or to contemplate integrating a more significant quantity. This coincides with the concerns of several international bodies, such as the United Nations and the World Bank, to give priority attention to themes related to how the construction industry comprehends the current and future situation of the RUE in the developing countries.
The features of the SFHs in developing countries will have a significant environmental impact on a global scale, which makes it necessary to establish clear and sustainable criteria for them [60]. Therefore, the significance of this study lies in the search for a way to achieve urban sustainability in the residential sector of MICs; this will be achieved by modifying the current paradigms with which the construction industry evaluates and builds millions of sustainable homes around the world.

2. Research Method

Four processes were developed to obtain housing indicators that would allow the concept of sustainability to be assimilated into the MIC’s cities using the characteristics of the RUE. The first defined the rating systems that were used as the basis for the analysis; the second selected the indicators that were the targets of the study; the third obtained the values of each of the chosen indicators; finally, the fourth performed a comparative analysis and obtained the total of the SHIRUEs with their respective descriptions and influence percentage ranges.

2.1. Definition of the Rating Systems

The definition of a SHRS considered those that are recognized by both the construction industry and the academic sector (Figure 1). The SHRSs were obtained from two independent processes. On the one hand, six systems were identified from the analysis of the 52 green building rating systems (GBRSs) recognized by the World Green Building Council (Figure 1a; [61]); on the other hand, a systematic review was carried out in which five systems were identified from the analysis of 226 articles published in journals indexed in Scopus (Figure 1b).
The rating systems’ definition process shows the significance of LEED and BREEAM as the most recognized schemes in the academic sector (Figure 1), which is in accordance with what has been shown by various studies [26,32,62,63]. Likewise, researchers show a clear lack of interest in the SHRSs developed by the MICs, given that just 7.5% of the studies analyzed in the systematic review only considered the GBI rating system [37,60,64,65].
The analyzed versions of each of the SHRSs correspond to those currently used by the construction industry (Table 1). Here, it is possible to identify three classes of systems: (i) those developed by a high-income country (HIC) with an international adoption, (ii) those developed by an upper-middle-income country (UMC) with a national adoption, and (iii) those developed by a lower-middle-income country (LMC) with a national adoption.
The SHRSs selected include contexts drawn from different regions of the planet; the East Asia and Pacific region show greater representativeness in this study with the consideration of the systems developed in Malaysia, Philippines, and Vietnam (Table 1). Moreover, the consideration of BERDE, BEST, CASA, Green Homes, and LOTUS provides added value to this work because they can be studied as a novel contribution to the knowledge in this subject developed thus far (Figure 1c).

2.2. Selection of the Single-Family Housing Indicators That Focuses on the Residential Urban Environment

The chosen indicators (SHIRUEs) correspond to those showing incidences in specific areas of the RUE around the SFH, i.e., in all the indicators in which the characteristics of the urban environment enable the housing to obtain a specific score. On the other hand, the analysis excluded all those indicators in which the required compliance criteria are performed in the private space of the dwelling, or in which there is a possibility of compliance through some activity carried out in the residence. The selection process is described in Figure 2, which ends with the consideration of four types of indicators: (i) SHOCIRUEentirely; (ii) SHOCIRUEpartially; (iii) SHMCIRUEentirely; and (iv) SHMCIRUEpartially.
The severance of the obligatory-criteria indicators (OCI) and the multi-criteria indicators (MCI) has been carried out in previous studies [60,76,77]. These showed that one of the advantages of following this process is that it produces results that refer directly to the green or sustainable characteristics considered intrinsic to each GBRT, while also allowing the analysis of the dispensable features without any constraints.
The determination of the partial and entire typologies was made because there are a considerable number of indicators in which only some of their compliance criteria focus on the qualities of the RUE. Likewise, there are also indicators in which all of their compliance criteria are related to the urban environment that surrounds the home.

2.3. Obtainment of the Values of the SHIRUEs

The current range of SHRSs allows the evaluation schemes to be adapted to their respective contexts; however, this complicates the comparative analysis of the different methodologies [78]. To overcome this impediment, this paper proposes the extraction of the corresponding values for each of the SHOCIRUE and SHMCIRUE.
To obtain the values that each SHRS assigns to each type of SHIRUE in relation to the other indicators, two equations are studied (Equations (1) and (2)), both in the SHOCIRUEs and in the SHMCIRUEs:
S H I R U E e n t i r e l y = ( I M a x / C M a x ) × W C I
where IMax is the maximum value assigned to the indicator by the SHRSs; CMax is the maximum value assigned to the category in which the indicator is located; and WCI is the weight of the category in which the indicator is located.
S H I R U E p a r t i a l l y = ( S H I R U E e n t i r e l y / I R T o t a l ) × I R R U E
where IRTotal is the total number of requirements established by the SHRS for the compliance of the indicator and IRRUE is the number of requirements that can be met through the RUE.
Regarding the WCI of each indicator, the one defined by each SHRS was used, except in those cases where the tool did not specify the weighting of each category; in this case, the values were obtained through Equation (3):
W C I = C M a x / C M a x
During the score obtainment process, all of the SHOCIRUEs were considered to have a value of one. Moreover, only 50% of the value of the indicators was considered in cases in which the SHIRUEs showed criteria that the house must necessarily meet in conjunction with the RUE (these indicators were considered as SHIRUEpartially), e.g., materials, where the RUE is required to have an infrastructure capable of providing a defined percentage of the dwelling. Additionally, some consideration was given to the different rating systems, as specified in Table 2.
Obtaining the values of each SHIRUE makes it possible to ascertain the maximum influence that the RUE has on each rating system (through quantitative data); this, in turn, allows the comparative analysis of the different systems to be carried out.

2.4. Comparative Analysis and Description of the SHIRUEs Identified

Li et al. [32] state that there are four levels of comparison among the rating systems: (i) general, (ii) category, (iii) criterion (sub-category), and (iv) indicator. This work focuses on the comparative analysis corresponding to level four. In this case, the criteria established by the systems are compared in each of the indicators, obtaining both the existing relationships between the different schemes, as well as those indicators of exclusive consideration by each of the systems, allowing new indicators to be identified and described.
The establishment of relationships among the rating systems means that any discussion of the results must involve a certain amount of complexity and subjectivity [79]; this uncertainty may be reduced by applying a criteria normalization process [24,60,80], which consists of reorganizing the selected indicators into new macro-areas (NMAs).
The process of clustering the indicators into the NMAs was based on the relationships between the SHRSs concerning the categories in which the SHIRUEs were identified. Once the indicators have been relocated in the NMAs, it was possible to discern their relationships, as well as to see the peculiarities that each SHRS establishes in its evaluation methodology.
Once the relationships were established between the SHIRUEs located in each NMA presented by each system, the maximum and minimum percentages of influence of each indicator were obtained. Additionally, the schemes that establish more rigorous compliance criteria were identified, as well as the more accessible compliance criteria.

3. Results and Discussion

The results and their discussion are presented in two sections: First, it shows the current situation of the conception that rating systems have of the RUE that surrounds the SFH, as well as the similarities and divergences among the systems. Second, it presents the identified indicators and their integration possibilities in the MICs, outlining the advantages that their use would have for these countries.

3.1. The RUE Recognized by the SHRSs: Their Influence and Relationships among the Schemes

This study notes that the urban environment recognized by the SHRSs needs to be addressed in a better way to provide housing that allows the sustainability of cities in the MICs to be improved. Based on each rating system’s own scheme, the maximum percentage of the RUE influence on the score of the housing varies according to the SHRS used. However, it is possible to establish a significant absence of the SHOCIRUEs among the rating systems, with CASA being the only system that considers the inclusion of this type of indicator, with a maximum influence of 3.15%. Furthermore, the study shows that none of the systems analyzed could achieve more than 18.86%, referring to the SHMCIRUEs (Figure 3).
Among the peculiarities of the SHRSs selected, LEED and CASA gave two paths to follow (performance—a, prescriptive—b); therefore, both scenarios were considered within the comparative analysis to reduce the sensitivity and uncertainty.
Table 3 shows the distribution of the indicators according to each of the typologies considered. It was found that the type corresponding to the SHIRUEentirely provides the most weight to the maximum percentage of influence. However, there are tools in which this does not occur. In CASA, the SHOCIRUEpartially were the only indicators; in LOTUS, the SHMCIRUEpartially made up more than double the value of the SHMCIRUEentirely; in Green Homes, the percentages between both types of SHMCIRUEs were equal. This highlights the weakness of the SHRSs of some MICs concerning the consideration of the RUE.
Among the SHRSs developed by a MIC, CASA stands out as the only system that considers both SHOCIRUEs and SHMCIRUEs. This may be a reflection of the practices implemented in Brazil in recent years, especially in social housing projects [22], where dwellings that have obtained more sustainable labeling have shown a high correlation of compliance with indicators related to urban quality [77]. In contrast to CASA, Green Homes was a system in which the RUE exerts the least influence on the housing score assigned for obtaining certification. This was possibly due to there being 0.23 accredited planners per 100,000 people in India [42], so the priorities of the residential sector can be unintentionally directed toward other areas. The aforementioned is of the utmost importance because India is considered one of the three countries where the highest world population growth will occur during the next 30 years [58].
Regarding the relationships among the SHRSs, most of the systems consider the categories associated with location, materials, and transport (Figure 4a). Moreover, most of the SHRSs exhibit more categories related to two or more systems than categories that are related to one or no systems (Figure 4b). Additionally, Figure 4 exhibits the case of GBI, which possessed the only category without any relationship with another system.
Each of the SHRSs has its own conception about how the urban environment impacts the labeling of housing and its maximum influence on the score; despite this, performing the normalization criteria process (NCP) allowed the identified indicators to be clustered into six new macro-areas (Figure 5): energy (ENE), innovation (INN), location (LCT), materials (MAT), transport (TRA), and waste (WST).
The clustering of the SHIRUEs into the NMAs (Figure 6) shows that BREEAM and CASA (b) included all the NMAs proposed, and Green Homes was the system with the lowest inclusion of the areas, considering only LCT and MAT. On the other hand, the percentages of distribution among the NMAs shown by each system varied significantly, with LEED (b) and BEST, and GBI and BERDE, being the rating systems that showed a closer distribution.
In Figure 6, ENE, INN, and WST have the lowest percentage of representation among the SHRSs. However, their consideration as NMA allowed for valuable information for the objectives of the study to be obtained: (i) In the case of ENE, several researchers have pointed out that there is a bias toward assigning a high weight to categories that promote energy efficiency in housing [32,33,82,83]. Despite this, in the SHMCIRUEs, only 63% of the systems considered them while emphasizing 100% of the tools developed by a UMC. (ii) Only BREEAM and LEED considered INN with a representativity of more than 10%. Furthermore, except for CASA, no system developed by an MIC contemplated the consideration of INN. (iii) The case of WST was unusual, as it was the second NMA that contained SHOCIRUEs, but concerning the SHMCIRUEs, only three of the eight systems recognized it as NMA, with values lower than 4% in CASA and LOTUS, and 12% in BREEAM.
Concerning the NMA of LCT, it is noteworthy that only CASA recognizes the SHOCIRUEs (Figure 7). Therefore, an analysis of the possible reasons for this situation could be addressed in future research. Moreover, despite the acceptance of this NMA by the different systems, the difficulty of finding correlations between them was evident.
TRA is another NMA in which all systems consider SHMCIRUEs; however, LEED (a), CASA (a), and Green Homes assess the inclusion, as optional compliance criteria of amenities in the area of LCT [69,70,72]. In this NMA, GBI stood out as the rating system with the highest influence percentage, while CASA (b) showed the lowest rates (Figure 8). Moreover, three indicators were the most studied quantities by the SHRSs. Additionally, a linear behavior was seen in the quantity–influence relation between the systems developed by the MICs.
Referring to the most significant NMAs: MAT could also be regarded as a relevant NMA, given that it was considered in all of the systems, although only by the SHMCIRUEs (Figure 9). In this NMA, both the quantities and the percentages of influence presented in each system differed considerably; however, it was noticeable that LOTUS had a more significant influence and number of indicators, showing values very different from those of the other SHRSs; GBI and BEST also had higher figures, with two indicators each and percentages from 2.27% to 3.00%. Additionally, the results showed a group in which all systems had only one indicator, but the rates of influence varied from 0.39% to 1.50%.
Finally, the fact that LCT and TRA were positioned as the NMAs where most of the SHRSs fit a higher distribution percentage, reaching 70% or more in the BREEAM, LEED (b), GBI, and BERDE rating systems (Figure 6), this could be considered understandable in terms of the urban environment. However, the consideration of ENE, INN, MAT, and WST validated the importance of carrying out detailed comparative analyses of the compliance criteria of the indicators between different rating systems.

3.2. The SHIRUEs Identified for Sustainable Cities in the Middle-Income Countries

A total of 39 SHIRUEs were identified to provide the broadest possible range of solutions to the concerns regarding the RUE of the MICs. In these indicators, a maximum influence percentage of 3.15% could be achieved in the case of the SHOCIRUEs, and up to 53.16% in the SHMCIRUEs (Figure 10). Furthermore, if the maximum percentage that could be reached by a system in the multi-criteria evaluation was from 2.67% in Green Homes (Figure 3), the consideration of the SHIRUEs and their maximum influence percentage could result in an increase up to 50.49% in the multi-criteria indicators.
The next sections provide an explanation of the 39 SHIRUEs identified concerning the SHOCIRUEs and the SHMCIRUEs.

3.2.1. The SHOCIRUEs Identified for Sustainable Cities in the Middle-Income Countries

As mentioned in previous sections, the identification of the SHOCIRUEs showed the null consideration that most systems had in their schemes, in which it was only possible to identify two indicators (Figure 8a). This nullity opens a new horizon in the academic field that allows for improvement in both the quantity and quality of these indicators. On the other hand, it is also striking that only the NMAs of LCT and WST were considered. In this study, it was only possible to identify two SHOCIRUEs, provided by CASA (Table 4).
At present, increasing pressure exists worldwide for the achievement of the sustainable use of surface water resources [84]. Moreover, in developing countries, water efficiency is considered a critical issue [83]. Since, as Narain and Singh stated [85], in countries such as India, some inhabitants have difficulty accessing water, any SHRS adopted in the MICs should consider the indicator of the “water systems” as an OCI in its evaluation methodology.
On the other hand, the identification of the “waste management” indicator should also be considered by other SHRSs. This is consistent with another study [37], which shows that issues related to waste management require more attention from rating systems; most systems can omit the use of this indicator, as very few consider it to be an aspect of mandatory compliance. Additionally, waste management has a significant impact on the sustainability of a city [86]. Nguyen et al. [46] state that the MICs must seek to achieve coordination among the stakeholders, market agencies, and local communities to enhance the sustainable qualities of the cities, as also indicated by CASA [70].

3.2.2. The SHMCIRUEs Identified for Sustainable Cities in the Middle-Income Countries

This study demonstrated that 31 of the 37 SHMCIRUEs identified were in the range of 0.2% to 1.0% relative to the minimum influence, and 0.2% to 2.0% concerning the maximum influence that each indicator can attain in the labeling of a house (Figure 11). This insignificance in terms of influence can be considered a reflection of the concerns shown by the New Urban Agenda regarding the lack of housing integration in the countries’ urban policies [42].
Future research should address the indicators that have a low percentage of influence in order to better understand the implications that the increase in these percentages could have on the sustainability of cities, as well as on the configuration of SFH (Figure 11b).
The description of the indicators is as follows: (i) the “certified neighborhood” indicator, (ii) the SHMCIRUEs that are considered by all SHRSs, (iii) the SHMCIRUEs that are particular to a single system, (iv) the SHMCIRUEs considered by two SHRSs, and (v) the SHMCIRUEs considered by three and five SHRSs.

The SHMCIRUE: Certified Neighborhood

Certified neighborhood is the indicator that had the highest influence percentages, and was widely differentiated from the other indicators (Figure 11a). This indicator was only contemplated by LEED and CASA, with CASA being the system that presents the most considerable flexibility in terms of compliance, but at the same time, its influence percentage was 4.55% lower than the percentage that could be obtained in LEED (Table 5).
It is plausible that a home located in a certified development must comply with the majority of the criteria indicated by the rest of the SHIRUEs. However, several investigations [87,88] point out that neighborhoods that have both certifications (such as the systems responsible for labeling the neighborhoods of the MICs) were not fully engaged with sustainable practices, especially in the case of social and affordable housing.

The SHMCIRUEs Considered by All SHRSs

Only two SHMCIRUEs are considered by all SHRSs: “public transport accessibility” and “proximity to amenities.” This indicates that even though the criteria among the systems varied concerning the needs of each country or region, these two indicators had universal applicability among the SHRSs. In these indicators, there were significant differences in the percentile ranges of the influence that each system considered in its evaluation methodology (Figure 11).
Except for LEED, CASA, and Green Homes, the other SHRSs considered that "public transport accessibility" is an indicator that generates better sustainable conditions for housing, because this indicator had more significant influence percentages (Figure 12); in LEED, the rates between both indicators were equivalent, while CASA and Green Homes valued the inclusion of this indicator among the amenities of an SFH. On the other hand, each system’s conception of the compliance criteria also varied significantly between the systems (Table 6 and Table 7).
One of the principal hypotheses that motivated this study was that it is necessary to view housing as an essential part in the development of communities [89]. In order to achieve a residential sector that contributes to increasing the livability of cities and to fit this hypothesis in the MICs, one of the main steps is that the process of urban planning and decision-making needs to establish a cross-relation between the availability of their amenities [90] and their public transport [34,91]. All the SHRSs understand the above, given that all consider the proximity of urban amenities and public transport to the house (Table 7). Nevertheless, the definition and compliance criteria of both indicators are extremely different in each of the SHRSs. Future research could focus on the description of which facilities and types of public transport, as well as their quantity, connectivity, and accessibility, are essential for consideration in a sustainable house. Additionally, the analysis of the inclusion of these indicators and their possible implications in obligatory-criteria assessment could be a significant step in assimilating sustainability into the cities of the MICs.

Exclusive SHMCIRUEs between the SHRSs

Among the indicators found, 16 of the 37 SHMCIRUEs were exclusive to LEED, BREEAM, GBI, or LOTUS (Figure 13), where BREEAM had higher quantities and LOTUS had the highest percentage of influence (8.75%). Moreover, “compact development” was the indicator that had the highest influence ranges; however, its consideration among MICs should be carefully considered. Hodson et al. [92] show different points of view within the scientific field for the consideration of this indicator.
Table 8 shows the description of every SHIMCIRUE. Similarly, in the case of indicators 3 and 14, it is notable that they have the same name, but were considered separately, because BREEAM performs this same differentiation based on the rigor established between their compliance criteria [67]. Finally, any of these indicators could be accepted as innovation criteria in any system that uses this category, such as LEED and CASA [69,70].

The SHMCIRUE Considered by Two SHRSs

A total of 35% of the indicators were obtained from the relationship between two SHRSs (Figure 14). Of these indicators, only three come from systems developed in an MIC, of which, the “construction noise” indicator, considered by BEST and LOTUS, can be counterproductive regarding increased social responsibility in the houses, because the fulfillment of this would mean that the house is located at a large distance from any public amenity.
Table 9 shows that, for the majority of the time, the systems that were more rigorous in terms of the compliance criteria corresponded to those that were developed in the country with the highest income level. The description of each indicator, as well as the established relationships, are provided in the Appendix A.

The SHMCIRUEs Considered by Three and Five SHRSs

According to Dall’O’ et al. [93], “The major causes of environmental impacts in urban areas can be linked to local traffic patterns.” Additionally, although recent studies [94,95] have demonstrated the importance of developing an environment that favors pedestrian mobility in the RUE, only BEST, CASA, and GBI establish this criterion as an important issue (Figure 15). However, their relative characteristics for consideration only deal with specific cases of determined routes followed by users, and so walkability is not considered in the general environs of the SFH.
Among the SHRSs, CASA has the most standardized indicators in the industry of global construction, given that it possesses most of the indicators that have relations between two or more systems (Table 9 and Table 10). On the other hand, the indicators “local materials,” “renewable energy,” and “security,” are only considered by systems developed in MICs; therefore, a more in-depth study in terms of these would be interesting in order to understand the implications they could have on the systems developed by an HIC. The description of each indicator, as well as the established relationships, are provided in the appendices.

4. Conclusions

This paper has provided 39 indicators (SHIRUEs) for assimilating sustainability into the cities of MICs by means of the RUE recognized by the SHRSs. The study provides an image of the current situation regarding how the SHRSs consider the influence of the RUE surrounding the SFH to determine the final label of a dwelling considered as sustainable, as well as the similarities and differences between the systems analyzed (BREEAM, LEED, BEST, CASA, GBI, BERDE, Green Homes, and LOTUS).
The main findings of this work have shown that the percentages of maximum influence obtained in the multi-criteria assessment and the lack of consideration of SHOCIRUEs in seven of the eight systems make certified sustainable housing possible; in which the urban environment does not meet the requirements to contribute to the sustainable development of the cities. This implies a bleak perspective for the objectives decided upon by the different countries in the new urban agenda, and also justifies the proposals of UN-Habitat III, which refers to the urgent need for different bodies (in the public and private sector) to collaborate to establish guidelines that will clarify the qualities necessary for a RUE to be considered sustainable.
The results indicate that deciding on a possible global homologation or standardization of the RUE’s inherent qualities in SFH is complex and will only be realized in the long-term. Although each system has its own conception of how the urban environment impacts the labeling of housing and its maximum influence on the score, carrying out the NCP allowed the identified indicators to be clustered into six new macro-areas: LCT, TRA, and MAT being the most important, with ENE, INN, and WST making up the rest.
The relationships among the SHRSs developed by a country with a specific income level shows that those developed in a HIC (LEED and BREEAM) had a higher number of requirements than those systems developed by an MIC and, in general, were more rigorous in terms of their compliance criteria. Consequently, this had a more significant effect on improving the urban environment. However, the rating systems developed by an MIC, such as CASA, GBI, and LOTUS, also have exclusive indicators, which could be applied in the systems developed by a HIC.
On the other hand, this study also shows the lack of interest on the part of the academic sector in analyzing the SHRSs that are developed by the UMC and LMC countries. However, the methods developed show that, although several studies state that BREEAM and LEED were the most widely recognized by the construction industry and academic sector, it was also essential to consider other SHRSs in the comparative analyses conducted to provide results in the MICs in order to acquire results that better match the specific features of these countries.
The use of the SHIRUEs identified can also have significant repercussions on the policies of the MICs because many of these countries base their urban guidelines on what is established by the rating systems. Therefore, it is expected that the identification of the two SHOCIRUEs and the 37 SHMCIRUEs could provide a variety of real and proven instruments, which will enable sustainable urban habitats to be obtained through the construction or evaluation of the SFH.
One of the main limitations of this work is that the view of the current situation of the RUE characteristics by the SHRSs cannot be considered complete, as a study of the scores obtained by real cases is missing. Moreover, some concerns were raised regarding the identified SHIRUEs during the discussion of the results, indicating the need for further investigation. Finally, the NCP carried out in this study has shown that there are criteria among the indicators that can be included in a different NMA as an exclusive indicator. Therefore, a more in-depth analysis of each criterion (or possibly a segregation of each) could lead to a more dynamic and effective understanding of the RUE, as well as the value that each SHRS gives to the requirements of each indicator.

Author Contributions

Conceptualization, H.S.-M. and J.M.G.-S.; methodology, H.S.-M., D.C.G.-G., and J.M.G.-S.; validation, S.P.A.-R.; formal analysis, H.S.-M. and J.M.G.-S.; investigation, D.C.G.-G. and R.C.-H.; resources, J.M.G.-S. and M.C.G.-S.; data curation, H.S.-M. and D.C.G.-G.; writing—original draft, H.S.-M. and S.P.A.-R..; writing—review and editing, M.C.G.-S.; supervision, S.P.A.-R. and R.C.-H; project administration, R.C.-H. and M.C.G.-S.; funding acquisition, J.M.G.-S.

Funding

This research received no external funding.

Acknowledgments

This work was supported by the National Council for Science and Technology (Spanish acronym: CONACYT) of Mexico. Acknowledgment also goes to the Sinaloa Institute of Support for Research and Innovation (Spanish acronym: INAPI) for making possible the development of this research.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

ENEEnergy
HICHigh-Income Country
INNInnovation
LCTLocation
LMCLower-Middle-Income Country
MATMaterials
MCIMulti-Criteria Indicators
MICMiddle-Income Country
NCPNormalization Criteria Process
NMANew Macro Area
OCIObligatory-Criteria Indicator
RUEResidential Urban Environment
SFHSingle-Family Housing
SHIRUESFH Indicator that focuses on the RUE
SHMCIRUESFH Multi-Criteria Indicator that focuses on the RUE
SHOCIRUESFH Obligatory-Criteria Indicator that focuses on the RUE
SHRSSingle-Family Housing Rating System
TRATransport
UMCUpper-Middle-Income Country
WSTWaste

Appendix A

Figure A1. Relationships among the SHIRUEs according to energy (ENE), innovation (INN), and waste (WST).
Figure A1. Relationships among the SHIRUEs according to energy (ENE), innovation (INN), and waste (WST).
Sustainability 11 04276 g0a1
Figure A2. Relationships among the SHIRUEs according to location (LCT).
Figure A2. Relationships among the SHIRUEs according to location (LCT).
Sustainability 11 04276 g0a2
Figure A3. Relationships among the SHIRUEs according to materials (MAT).
Figure A3. Relationships among the SHIRUEs according to materials (MAT).
Sustainability 11 04276 g0a3
Figure A4. Relationships among the SHIRUEs according to the Transport (TRA).
Figure A4. Relationships among the SHIRUEs according to the Transport (TRA).
Sustainability 11 04276 g0a4

References

  1. United Nations. World Population Prospects: The 2017 Revision, Key Findings and Advance Tables; United Nations: New York, NY, USA, 2017. [Google Scholar]
  2. Wang, C.; Wang, Z.H. Projecting population growth as a dynamic measure of regional urban warming. Sustain. Cities Soc. 2017, 32, 357–365. [Google Scholar] [CrossRef] [Green Version]
  3. Mi, Z.; Guan, D.; Liu, Z.; Liu, J.; Viguié, V.; Fromer, N.; Wang, Y. Cities: The core of climate change mitigation. J. Clean. Prod. 2019, 207, 582–589. [Google Scholar] [CrossRef]
  4. Mahmoud, S.H.; Gan, T.Y. Long-term impact of rapid urbanization on urban climate and human thermal comfort in hot-arid environment. Build. Environ. 2018, 142, 83–100. [Google Scholar] [CrossRef]
  5. The World Bank. The International Monetary Fund Development Goals in an Era of Demographic Change. Available online: http://pubdocs.worldbank.org/en/503001444058224597/Global-Monitoring-Report-2015.pdf (accessed on 7 February 2018).
  6. Dizdaroglu, D. The role of indicator-based sustainability assessment in policy and the decision-making process: A review and outlook. Sustainability 2017, 9, 1018. [Google Scholar] [CrossRef]
  7. Haase, D.; Kabisch, S.; Haase, A.; Andersson, E.; Banzhaf, E.; Baró, F.; Brenck, M.; Fischer, L.K.; Frantzeskaki, N.; Kabisch, N.; et al. Greening cities—To be socially inclusive? About the alleged paradox of society and ecology in cities. Habitat Int. 2017, 64, 41–48. [Google Scholar] [CrossRef]
  8. Albertí, J.; Roca, M.; Brodhag, C.; Fullana-i-Palmer, P. Allocation and system boundary in life cycle assessments of cities. Habitat Int. 2019, 83, 41–54. [Google Scholar] [CrossRef]
  9. Balasbaneh, A.T.; Bin Marsono, A.K. Strategies for reducing greenhouse gas emissions from residential sector by proposing new building structures in hot and humid climatic conditions. Build. Environ. 2017, 124, 357–368. [Google Scholar] [CrossRef]
  10. Flood, J. Urban and Housing Indicators. Urban Stud. 1997, 34, 1635–1665. [Google Scholar] [CrossRef]
  11. Norouzian-Maleki, S.; Bell, S.; Hosseini, S.-B.; Faizi, M. Developing and testing a framework for the assessment of neighbourhood liveability in two contrasting countries: Iran and Estonia. Ecol. Indic. 2015, 48, 263–271. [Google Scholar] [CrossRef] [Green Version]
  12. Waitt, G.; Knobel, H. Embodied geographies of liveability and urban parks. Urban Stud. 2018, 55, 3151–3167. [Google Scholar] [CrossRef]
  13. Moulay, A.; Ujang, N.; Maulan, S.; Ismail, S. Understanding the process of parks’ attachment: Interrelation between place attachment, behavioural tendencies, and the use of public place. City Cult. Soc. 2018, 14, 28–36. [Google Scholar] [CrossRef]
  14. Mahmoudi, M.; Ahmad, F.; Abbasi, B. Livable streets: The effects of physical problems on the quality and livability of Kuala Lumpur streets. Cities 2015, 43, 104–114. [Google Scholar] [CrossRef]
  15. Villanueva, K.; Badland, H.; Hooper, P.; Koohsari, M.J.; Mavoa, S.; Davern, M.; Roberts, R.; Goldfeld, S.; Giles-Corti, B. Developing indicators of public open space to promote health and wellbeing in communities. Appl. Geogr. 2015, 57, 112–119. [Google Scholar] [CrossRef]
  16. Wilcox, J.A. The Home Purchase Sentiment Index: A New Housing Indicator. Bus. Econ. 2015, 50, 178–190. [Google Scholar] [CrossRef]
  17. Monzón, M.; López-Mesa, B. Buildings performance indicators to prioritise multi-family housing renovations. Sustain. Cities Soc. 2018, 38, 109–122. [Google Scholar] [CrossRef]
  18. Barreca, A.; Curto, R.; Rolando, D. Housing vulnerability and property prices: Spatial analyses in the Turin Real Estate Market. Sustainability 2018, 10, 3068. [Google Scholar] [CrossRef]
  19. Shama, Z.S.; Motlak, J.B. Indicators for Sustainable housing. IOP Conf. Ser. Mater. Sci. Eng. 2019, 518, 022009. [Google Scholar] [CrossRef]
  20. Morganti, M.; Pages-Ramon, A.; Coch, H. Buildingmass and Energy Demand in Conventional Housing Typologies of the Mediterranean City. Sustainability 2019, 11, 3540. [Google Scholar] [CrossRef]
  21. Llera-Sastresa, E.; Scarpellini, S.; Rivera-Torres, P.; Aranda, J.; Zabalza-Bribián, I.; Aranda-Usón, A. Energy vulnerability composite index in social housing, from a household energy poverty perspective. Sustainability 2017, 9, 691. [Google Scholar] [CrossRef]
  22. Siqueira-Gay, J.; Gallardo, A.L.C.F.; Giannotti, M. Integrating socio-environmental spatial information to support housing plans. Cities 2019, 91, 106–115. [Google Scholar] [CrossRef]
  23. Kajikawa, Y.; Inoue, T.; Goh, T.N. Analysis of building environment assessment frameworks and their implications for sustainability indicators. Sustain. Sci. 2011, 6, 233–246. [Google Scholar] [CrossRef]
  24. Mattoni, B.; Guattari, C.; Evangelisti, L.; Bisegna, F.; Gori, P.; Asdrubali, F. Critical review and methodological approach to evaluate the differences among international green building rating tools. Renew. Sustain. Energy Rev. 2018, 82, 950–960. [Google Scholar] [CrossRef]
  25. Bernardi, E.; Carlucci, S.; Cornaro, C.; Bohne, R.A. An analysis of the most adopted rating systems for assessing the environmental impact of buildings. Sustainability 2017, 9, 1226. [Google Scholar] [CrossRef]
  26. Suzer, O. Analyzing the compliance and correlation of LEED and BREEAM by conducting a criteria-based comparative analysis and evaluating dual-certified projects. Build. Environ. 2019, 147, 158–170. [Google Scholar] [CrossRef]
  27. Li, J.; Huang, X.; Kwan, M.P.; Yang, H.; Chuai, X. The effect of urbanization on carbon dioxide emissions efficiency in the Yangtze River Delta, China. J. Clean. Prod. 2018, 188, 38–48. [Google Scholar] [CrossRef]
  28. Zarghami, E.; Azemati, H.; Fatourehchi, D.; Karamloo, M. Customizing well-known sustainability assessment tools for Iranian residential buildings using Fuzzy Analytic Hierarchy Process. Build. Environ. 2018, 128, 107–128. [Google Scholar] [CrossRef]
  29. Díaz-López, C.; Carpio, M.; Martín-Morales, M.; Zamorano, M. A comparative analysis of sustainable building assessment methods. Sustain. Cities Soc. 2019, 49, 101611. [Google Scholar] [CrossRef]
  30. Gou, Z.; Xie, X. Evolving green building: Triple bottom line or regenerative design? J. Clean. Prod. 2017, 153, 600–607. [Google Scholar] [CrossRef]
  31. Jato-Espino, D.; Yiwo, E.; Rodriguez-Hernandez, J.; Canteras-Jordana, J.C. Design and application of a Sustainable Urban Surface Rating System (SURSIST). Ecol. Indic. 2018, 93, 1253–1263. [Google Scholar] [CrossRef]
  32. Li, Y.; Chen, X.; Wang, X.; Xu, Y.; Chen, P.H. A review of studies on green building assessment methods by comparative analysis. Energy Build. 2017, 146, 152–159. [Google Scholar] [CrossRef]
  33. Chen, X.; Yang, H.; Lu, L. A comprehensive review on passive design approaches in green building rating tools. Renew. Sustain. Energy Rev. 2015, 50, 1425–1436. [Google Scholar] [CrossRef]
  34. Huo, X.; Yu, A.T.W.; Wu, Z. A comparative analysis of site planning and design among green building rating tools. J. Clean. Prod. 2017, 147, 352–359. [Google Scholar] [CrossRef]
  35. Park, J.; Yoon, J.; Kim, K.H. Critical review of the material criteria of building sustainability assessment tools. Sustainability 2017, 9, 186. [Google Scholar] [CrossRef]
  36. Stankovic, B.; Kostic, A.; Popovic, M.J. Analysis and comparison of lighting design criteria in green building certification systems -Guidelines for application in Serbian building practice. Energy Sustain. Dev. 2014, 19, 56–65. [Google Scholar] [CrossRef]
  37. Wu, Z.; Shen, L.; Yu, A.T.W.; Zhang, X. A comparative analysis of waste management requirements between five green building rating systems for new residential buildings. J. Clean. Prod. 2016, 112, 895–902. [Google Scholar] [CrossRef]
  38. Abu Bakar, N.N.; Hassan, M.Y.; Abdullah, H.; Rahman, H.A.; Abdullah, M.P.; Hussin, F.; Bandi, M. Energy efficiency index as an indicator for measuring building energy performance: A review. Renew. Sustain. Energy Rev. 2015, 44, 1–11. [Google Scholar] [CrossRef]
  39. Michael, F.L.; Noor, Z.Z.; Figueroa, M.J. Review of urban sustainability indicators assessment—Case study between Asian countries. Habitat Int. 2014, 44, 491–500. [Google Scholar] [CrossRef]
  40. Shen, L.Y.; Jorge Ochoa, J.; Shah, M.N.; Zhang, X. The application of urban sustainability indicators—A comparison between various practices. Habitat Int. 2011, 35, 17–29. [Google Scholar] [CrossRef]
  41. Pupphachai, U.; Zuidema, C. Sustainability indicators: A tool to generate learning and adaptation in sustainable urban development. Ecol. Indic. 2017, 72, 784–793. [Google Scholar] [CrossRef]
  42. UN-Habitat. Habitat III Issue Papers; United Nations: New York, NY, USA, 2017. [Google Scholar]
  43. Andrić, I.; Le Corre, O.; Lacarrière, B.; Ferrão, P.; Al-Ghamdi, S.G. Initial approximation of the implications for architecture due to climate change. Adv. Build. Energy Res. 2019. [Google Scholar] [CrossRef]
  44. Roshan, G.R.; Oji, R.; Attia, S. Projecting the impact of climate change on design recommendations for residential buildings in Iran. Build. Environ. 2019, 155, 283–297. [Google Scholar] [CrossRef] [Green Version]
  45. Bahadure, S.; Kotharkar, R. Framework for measuring sustainability of neighbourhoods in Nagpur, India. Build. Environ. 2018, 127, 86–97. [Google Scholar] [CrossRef]
  46. Nguyen, T.T.P.; Zhu, D.; Le, N.P. Factors influencing waste separation intention of residential households in a developing country: Evidence from Hanoi, Vietnam. Habitat Int. 2015, 48, 169–176. [Google Scholar] [CrossRef]
  47. Cáceres Seguel, C.; Ahumada Villaroel, G. Evaluación de brechas de equipamiento urbano entre barrios de Viña del Mar, Chile: Una metodología para la identificación de desiertos urbanos. Investig. Geogr. 2018. [Google Scholar] [CrossRef]
  48. Arimah, B.C. Housing-sector performance in global perspective: A cross-city investigation. Urban Stud. 2000, 37, 2551–2579. [Google Scholar] [CrossRef]
  49. Rodríguez Serrano, A.Á.; Porras Álvarez, S. Life cycle assessment in building: A case study on the energy and emissions impact related to the choice of housing typologies and construction process in Spain. Sustainability 2016, 8, 287. [Google Scholar] [CrossRef]
  50. Wang, N.; Phelan, P.E.; Gonzalez, J.; Harris, C.; Henze, G.P.; Hutchinson, R.; Langevin, J.; Lazarus, M.A.; Nelson, B.; Pyke, C.; et al. Ten questions concerning future buildings beyond zero energy and carbon neutrality. Build. Environ. 2017, 119, 169–182. [Google Scholar] [CrossRef] [Green Version]
  51. Soares, N.; Bastos, J.; Dias Pereira, L.; Soares, A.; Amaral, A.R.; Asadi, E.; Rodrigues, E.; Lamas, F.B.; Monteiro, H.; Lopes, M.A.R.; et al. A review on current advances in the energy and environmental performance of buildings towards a more sustainable built environment. Renew. Sustain. Energy Rev. 2017, 77, 845–860. [Google Scholar] [CrossRef]
  52. Pisello, A.L.; Taylor, J.E.; Xu, X.; Cotana, F. Inter-building effect: Simulating the impact of a network of buildings on the accuracy of building energy performance predictions. Build. Environ. 2012, 58, 37–45. [Google Scholar] [CrossRef]
  53. Soust-Verdaguer, B.; Llatas, C.; García-Martínez, A. Simplification in life cycle assessment of single-family houses: A review of recent developments. Build. Environ. 2016, 103, 215–227. [Google Scholar] [CrossRef] [Green Version]
  54. Enteria, N.; Cuartero, O. A Review of the Recent Development of the Philippine Household Tech-nologies and Energy Consumption. Recent Pat. Eng. 2017, 11, 35–48. [Google Scholar] [CrossRef]
  55. Lavagna, M.; Baldassarri, C.; Campioli, A.; Giorgi, S.; Dalla Valle, A.; Castellani, V.; Sala, S. Benchmarks for environmental impact of housing in Europe: Definition of archetypes and LCA of the residential building stock. Build. Environ. 2018, 145, 260–275. [Google Scholar] [CrossRef]
  56. UN-Habitat. Urbanization and Development: Emerging Futures; UN-Habitat: Nairobi, Kenya, 2016. [Google Scholar]
  57. The World Bank. 3 Big Ideas to Achieve Sustainable Cities and Communities. Available online: http://www.worldbank.org/en/news/immersive-story/2018/01/31/3-big-ideas-to-achieve-sustainable-cities-and-communities (accessed on 1 January 2019).
  58. United Nations. World Urbanization Prospects: The 2018 Revision; United Nations: New York, NY, USA, 2018. [Google Scholar]
  59. Papargyropoulou, E.; Padfield, R.; Harrison, O.; Preece, C. The rise of sustainability services for the built environment in Malaysia. Sustain. Cities Soc. 2012, 5, 44–51. [Google Scholar] [CrossRef]
  60. Saldaña-Márquez, H.; Gómez-Soberón, J.M.; Arredondo-Rea, S.P.; Gámez-García, D.C.; Corral-Higuera, R. Sustainable social housing: The comparison of the Mexican funding program for housing solutions and building sustainability rating systems. Build. Environ. 2018, 133, 103–122. [Google Scholar] [CrossRef]
  61. WorldGBC Rating Tools. Available online: http://www.worldgbc.org/rating-tools (accessed on 11 February 2019).
  62. Seinre, E.; Kurnitski, J.; Voll, H. Building sustainability objective assessment in Estonian context and a comparative evaluation with LEED and BREEAM. Build. Environ. 2014, 82, 110–120. [Google Scholar] [CrossRef]
  63. Ferreira, J.; Pinheiro, M.D.; De Brito, J. Portuguese sustainable construction assessment tools benchmarked with BREEAM and LEED: An energy analysis. Energy Build. 2014, 69, 451–463. [Google Scholar] [CrossRef]
  64. Mohammed Usman, A.; Abdullah, K. Comparative Study on the Malaysian Sustainable Building Rating Systems. Int. J. Integr. Eng. 2018, 10, 69–77. [Google Scholar] [CrossRef]
  65. Shafiei, M.W.M.; Abadi, H.; Osman, W.N. The indicators of green buildings for Malaysian property development industry. Int. J. Appl. Eng. Res. 2017, 12, 2182–2189. [Google Scholar]
  66. PHILGBC BERDE GBRS—New Construction. V2.2.0. Available online: http://docs.berdeonline.org/userguide/v2.0.0/berde-nc/#copyright (accessed on 1 September 2018).
  67. Global, B. BREEAM International New Construction 2016; Technical Manual SD233 2.0: Watford, UK, 2017. [Google Scholar]
  68. ÇEDBİK. Çedbik-Konut Sertifika Kilavuzu. Yeni konutlar V.1; ÇEDBİK: Istanbul, Turkey, 2018. [Google Scholar]
  69. USGBC. LEED V4 for Homes Design and Construction; USGBC: Washington, DC, USA, 2013. [Google Scholar]
  70. GBC BRASIL. Certificação GBC Brasil Casa; GBC BRASIL: Sao Paulo, Brazil, 2017. [Google Scholar]
  71. GSB. GBI Residential New Construction (RNC) Design Reference Guide and Submission Format. V 3.1; GSB: Kuala Lumpur, Malaysia, 2014. [Google Scholar]
  72. IGBC. IGBC Green Homes Rating System V 2.0; IGBC: Hyderabad, India, 2012. [Google Scholar]
  73. VGBC. LOTUS Homes V1. Technical Manual; VGBC: Hanoi, Vietnam, 2017. [Google Scholar]
  74. IGBC. IGBC Green Homes Rating System—V 2.0 First Addendum; IGBC: Hyderabad, India, 2014. [Google Scholar]
  75. IGBC. IGBC Green Homes Rating System—V 2.0 Second Addendum; IGBC: Hyderabad, India, 2016. [Google Scholar]
  76. Ameen, R.F.M.; Mourshed, M.; Li, H. A critical review of environmental assessment tools for sustainable urban design. Environ. Impact Assess. Rev. 2015, 55, 110–125. [Google Scholar] [CrossRef]
  77. Fastofski, D.C.; González, M.A.S.; Kern, A.P. Sustainability analysis of housing developments through the Brazilian environmental rating system Selo Casa Azul. Habitat Int. 2017, 67, 44–53. [Google Scholar] [CrossRef]
  78. De Boeck, L.; Verbeke, S.; Audenaert, A.; De Mesmaeker, L. Improving the energy performance of residential buildings: A literature review. Renew. Sustain. Energy Rev. 2015, 52, 960–975. [Google Scholar] [CrossRef]
  79. Illankoon, I.M.C.S.; Tam, V.W.Y.; Le, K.N.; Shen, L. Key credit criteria among international green building rating tools. J. Clean. Prod. 2017, 164, 209–220. [Google Scholar] [CrossRef]
  80. Asdrubali, F.; Baldinelli, G.; Bianchi, F.; Sambuco, S. A comparison between environmental sustainability rating systems LEED and ITACA for residential buildings. Build. Environ. 2015, 86, 98–108. [Google Scholar] [CrossRef]
  81. The World Bank Data GNI per Capita, Atlas Method (Current US$). Available online: https://data.worldbank.org/indicator/NY.GNP.PCAP.CD?locations=GB-US-PH-IN-VN-TR-BR-MY (accessed on 24 February 2019).
  82. Shan, M.; Hwang, B. Green building rating systems: Global reviews of practices and research efforts. Sustain. Cities Soc. 2018, 39, 172–180. [Google Scholar] [CrossRef]
  83. Zarghami, E.; Fatourehchi, D.; Karamloo, M. Establishing a region-based rating system for multi-family residential buildings in Iran: A holistic approach to sustainability. Sustain. Cities Soc. 2019, 50, 101631. [Google Scholar] [CrossRef]
  84. Hoslett, J.; Massara, T.M.; Malamis, S.; Ahmad, D.; van den Boogaert, I.; Katsou, E.; Ahmad, B.; Ghazal, H.; Simons, S.; Wrobel, L.; et al. Surface water filtration using granular media and membranes: A review. Sci. Total Environ. 2018, 639, 1268–1282. [Google Scholar] [CrossRef]
  85. Narain, V.; Singh, A.K. Replacement or displacement? Periurbanisation and changing water access in the Kumaon Himalaya, India. Land Use Policy 2019, 82, 130–137. [Google Scholar] [CrossRef]
  86. Vilčeková, S.; Selecká, I.; Burdová, E.K.; Mečiarová, L. Interlinked sustainability aspects of low-rise residential family house development in Slovakia. Sustainability 2018, 10, 3966. [Google Scholar] [CrossRef]
  87. Komeily, A.; Srinivasan, R.S. A need for balanced approach to neighborhood sustainability assessments: A critical review and analysis. Sustain. Cities Soc. 2015, 18, 32–43. [Google Scholar] [CrossRef]
  88. Charoenkit, S.; Kumar, S. Environmental sustainability assessment tools for low carbon and climate resilient low income housing settlements. Renew. Sustain. Energy Rev. 2014, 38, 509–525. [Google Scholar] [CrossRef]
  89. Abdellatif, M.; Al-Shamma’a, A. Review of sustainability in buildings. Sustain. Cities Soc. 2015, 14, 171–177. [Google Scholar] [CrossRef]
  90. Cabrera-Barona, P. Influence of Urban Multi-Criteria Deprivation and Spatial Accessibility to Healthcare on Self-Reported Health. Urban Sci. 2017, 1, 11. [Google Scholar] [CrossRef]
  91. Mugion, R.G.; Toni, M.; Raharjo, H.; Di Pietro, L.; Sebathu, S.P. Does the service quality of urban public transport enhance sustainable mobility? J. Clean. Prod. 2018, 174, 1566–1587. [Google Scholar] [CrossRef]
  92. Hodson, M.; Geels, F.W.; McMeekin, A. Reconfiguring urban sustainability transitions, analysing multiplicity. Sustainability 2017, 9, 299. [Google Scholar] [CrossRef]
  93. Dall’O’, G.; Galante, A.; Sanna, N.; Miller, K. On the integration of leadership in energy and environmental design (LEED) ND protocol with the energy planning and management tools in Italy: Strengths and weaknesses. Energies 2013, 6, 5990–6015. [Google Scholar] [CrossRef]
  94. Gámez-García, D.C.; Saldaña-Márquez, H.; Gómez-Soberón, J.M.; Corral-Higuera, R.; Arredondo-Rea, S.P. Life Cycle Assessment of residential streets from the perspective of favoring the human scale and reducing motorized traffic flow. From cradle to handover approach. Sustain. Cities Soc. 2019, 44, 332–342. [Google Scholar] [CrossRef]
  95. Kang, C.D. Spatial access to pedestrians and retail sales in Seoul. Korea. Habitat Int. 2016, 57, 110–120. [Google Scholar] [CrossRef]
Figure 1. Flowchart of the single-family housing rating systems (SHRSs) definition: (a) the SHRSs identification by a decisive hierarchical process according to the systems identified by The World Green Building Council, (b) the identification of the SHRSs with an international adoption through a systematic review, and (c) definition of the SHRSs.
Figure 1. Flowchart of the single-family housing rating systems (SHRSs) definition: (a) the SHRSs identification by a decisive hierarchical process according to the systems identified by The World Green Building Council, (b) the identification of the SHRSs with an international adoption through a systematic review, and (c) definition of the SHRSs.
Sustainability 11 04276 g001
Figure 2. Flowchart of the selection of the SHIRUEs.
Figure 2. Flowchart of the selection of the SHIRUEs.
Sustainability 11 04276 g002
Figure 3. Maximum influence and quantities according to the single-family housing indicators concerning RUE characteristics (SHIRUEs) identified on the SHRS: (a) results according to the SHOCIRUEs, and (b) results according to the SHMCIRUEs. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Figure 3. Maximum influence and quantities according to the single-family housing indicators concerning RUE characteristics (SHIRUEs) identified on the SHRS: (a) results according to the SHOCIRUEs, and (b) results according to the SHMCIRUEs. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Sustainability 11 04276 g003
Figure 4. Relations between the categories established by each SHRS and the remaining systems: (a) categories in which there are relationships between all systems and in which there are no relationships, and (b) categories in which there are relationships between the systems.
Figure 4. Relations between the categories established by each SHRS and the remaining systems: (a) categories in which there are relationships between all systems and in which there are no relationships, and (b) categories in which there are relationships between the systems.
Sustainability 11 04276 g004
Figure 5. Scheme of the normalization criteria process (NCP).
Figure 5. Scheme of the normalization criteria process (NCP).
Sustainability 11 04276 g005
Figure 6. Maximum influence of the SHIRUEs and their distribution according to each NMA.
Figure 6. Maximum influence of the SHIRUEs and their distribution according to each NMA.
Sustainability 11 04276 g006
Figure 7. Maximum influence and quantities according to the SHIRUEs identified in the SHRS, according to LCT: (a) results according to the SHOCIRUEs, and (b) results according to the SHMCIRUEs. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Figure 7. Maximum influence and quantities according to the SHIRUEs identified in the SHRS, according to LCT: (a) results according to the SHOCIRUEs, and (b) results according to the SHMCIRUEs. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Sustainability 11 04276 g007
Figure 8. Maximum influence and quantities according to the SHMCIRUEs identified on the SHRS, according to TRA. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Figure 8. Maximum influence and quantities according to the SHMCIRUEs identified on the SHRS, according to TRA. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Sustainability 11 04276 g008
Figure 9. Maximum influence and quantities according to the SHMCIRUEs identified on the SHRS, according to MAT: (a) results according to the SHMCIRUEs, and (b) zoom of the SHMCIRUEs. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Figure 9. Maximum influence and quantities according to the SHMCIRUEs identified on the SHRS, according to MAT: (a) results according to the SHMCIRUEs, and (b) zoom of the SHMCIRUEs. The size of the points corresponds to the GNI per capita [81] of the country in which the system was developed.
Sustainability 11 04276 g009
Figure 10. Maximum influence and quantities according to the SHIRUEs identified on the NMAs: (a) results according to the SHOCIRUEs, and (b) results according to the SHMCIRUEs.
Figure 10. Maximum influence and quantities according to the SHIRUEs identified on the NMAs: (a) results according to the SHOCIRUEs, and (b) results according to the SHMCIRUEs.
Sustainability 11 04276 g010
Figure 11. SHMCIRUEs identified: (a) full picture of the SHMCIRUEs identified, and (b) zoom of the SHMCIRUEs. The size of the points corresponds to the quantity of SHRSs that consider the indicator.
Figure 11. SHMCIRUEs identified: (a) full picture of the SHMCIRUEs identified, and (b) zoom of the SHMCIRUEs. The size of the points corresponds to the quantity of SHRSs that consider the indicator.
Sustainability 11 04276 g011
Figure 12. SHMCIRUEs considered by all SHRSs. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Figure 12. SHMCIRUEs considered by all SHRSs. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Sustainability 11 04276 g012
Figure 13. Exclusive SHMCIRUEs identified. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Figure 13. Exclusive SHMCIRUEs identified. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Sustainability 11 04276 g013
Figure 14. SHMCIRUEs considered by two SHRSs. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Figure 14. SHMCIRUEs considered by two SHRSs. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Sustainability 11 04276 g014
Figure 15. SHMCIRUEs considered by three and five SHRSs. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Figure 15. SHMCIRUEs considered by three and five SHRSs. The size of the points corresponds to the sum of the GNI per capita [81] of the countries in which the systems were developed.
Sustainability 11 04276 g015
Table 1. Description of the SHRSs.
Table 1. Description of the SHRSs.
SHRSVersion–YearCountry–Income LevelAdoptionScoring: Rating System
BREEAMSD233 2.0–2016 AUnited Kingdom (GBR)–HICInternational% Score: Pass (≥ 30), Good (≥ 45), Very good (≥ 55), Excellent (≥ 70), Outstanding (≥ 85).
LEEDV4 BD+C–2013United States (USA)–HICInternationalPoints: Certified (40–49), Silver (50–59), Gold (60–79), Platinum (80+).
BEST1.0–2018Turkey (TUR)–UMCNationalPoints: Approved (45–64), Good (65–79), Very good (80–99), Excellent (100).
CASACASA–2017Brazil (BRA)–UMCNationalPoints: Certified (40–49), Silver (50–59), Gold (60–79), Platinum (80+).
GBIRNC 3.1–2014Malaysia (MYS)–UMCNationalPoints: Certified (50–65), Silver (66–75), Gold (76–85), Platinum (86+).
BERDENC 2.2.0–2018Philippines (PHL)–LMCNationalStars: 1 Star (51–60 points), 2 Star (61–70 points), 3 Star (71–80 points), 4 Star (81–90 points), 5 Star (91+ points).
Green Homes2.0–2012 BIndia (IND)–LMCNationalPoints: Certified (38–44), Silver (45–51), Gold (52–59), Platinum (60–75).
LOTUSHomes V1–2017Vietnam (VNM)–LMCNationalPoints: Certified (32–43), Silver (44–51), Gold (52–59), Platinum (60+).
References: [66,67,68,69,70,71,72,73]. A Only "partially fitted" was considered. B Includes Addendum of October 2016 and January 2014 [74,75].
Table 2. Considerations made in the selected SHRS.
Table 2. Considerations made in the selected SHRS.
SHRSSpecial Considerations
BREEAMBREEAM allows the weights of each category to differ regarding the location of the home in which the certification is to be made. Therefore, to obtain a quantitative analysis with the least possible bias, all the WCIs were obtained using Equation (3). On the other hand, the OCIs vary according to the rating level desired; however, for this analysis, those required for a “pass” level were addressed. In addition, the SHMCIRUEs indicated in the innovation category were considered to be independent of the categories to which they refer to respect the weight that should correspond to them.
LEEDThe point floors were discarded.
BERDEThe four OCIs presented by this tool are located in the categories of management (MN), and use of land and ecology (LE). In the MN category, the OCIs were located in the commitment to sharing resource data, and compliance with building and environmental laws, regulations, and mandatory standards. The other two OCIs were located in the LE category: distinct and clear boundaries, and initial site assessment. Finally, each OCI was considered with a value of 0.25.
BESTThe available points in Table 1 (see Reference [68]) were considered to obtain the maximum values granted by the SHRS for each indicator.
LOTUSThe categories of innovation (INN) and best practice credits (BPC) were discarded, both in the OCIs and in the MCIs, because the tool does not consider a specific weight for this category.
Note: There are no special considerations in the SHRS: CASA, GBI, and Green Homes.
Table 3. Quantity and weight of the SHIRUE identified in the SHRSs.
Table 3. Quantity and weight of the SHIRUE identified in the SHRSs.
SHRSAdoptionSHOCIRUEpartiallySHMCIRUEpartiallySHMCIRUEentirely
Qty.% *Qty.% *Qty.% *
BREEAMInternational--62.2557.81
LEED (a) --10.68417.27
LEED (b) --10.681014.55
BESTNational in a UMC--33.64510.00
CASA (a) 23.1564.32414.55
CASA (b) 23.1564.32611.82
GBI --21.50617.00
BERDENational in an LMC--22.5048.00
Green Homes --11.3311.33
LOTUS --810.1935.00
* Maximum percentage of influence that can be achieved with the compliance of the indicators. (a) and (b) refer to the performance and prescriptive paths, respectively.
Table 4. Description of the SHOCIRUEs.
Table 4. Description of the SHOCIRUEs.
Indicator Influence (%)The Influence Percentage Is Obtained When the Urban Environment:
1. Water Systems1.47Has an infrastructure network from which the house can be fed (sewage treatment and water supply network).
2. Waste Management1.68Has market agents that act in the reception of waste and waste transporters that comply with the operational requirements established in laws and regulations.
Reference: [70].
Table 5. Description of the “certified neighborhood” indicator.
Table 5. Description of the “certified neighborhood” indicator.
Considered by: Influence (%)The Influence Percentage Is Obtained When the Urban Environment:
LEED13.64Complies with LEED certification for neighborhood development.
CASA9.09Complies with an environmental certification from a recognized certification body, such as AQUA-HQE Districts and Lots, LEED-ND, BREEAM Communities or SITES.
References: [69,70].
Table 6. Description of the “public transport accessibility” indicator.
Table 6. Description of the “public transport accessibility” indicator.
Considered by: Influence (%)The Influence Percentage Is Obtained When the Urban Environment:
BREEAM0.78–3.13Has a public transport accessibility index (AI) for the assessed SFH ≥ 0.5, 1, 2, or 4.
LEED0.91–1.82Has a bus or streetcar stop within 400 m walking distance from the SFH or bus rapid transit stops, light or heavy rail stations, or ferry terminals within 800 m walking distance. With a transit service that meets the minimum daily transit service for projects with multiple transit types; weekday trips = 72, 144, or 360; weekend trips = 40, 108, or 216; or minimum daily transit service for projects with commuter rail or ferry service only: weekday trips = 24, 40, or 60.
BEST2.73Has a public transportation point within 500 m from the SFH.
GBI2.00–6.00Has public transport stop with one route within 500 m from the SFH; and/or has public transport interchange with same mode of transport with more than one route, within 750 m from the SFH; and/or has a public transport interchange with more than one mode of transport (e.g., bus, monorail, train, ferry, etc.), within 1 km from the SFH.
BERDE1.00–4.00Has one or two public transport services: existing or currently planned funded commuter rail or light rail within 500 m walking distance; a bus stop for at least two public, campus, or private bus lines within 500 m walking distance; stop for at least two Asian utility vehicle (AUV) or public utility vehicle (PUV) routes within 250 m walking distance; shuttle service provided for the users from the SFH to any public transportation stops or stations; and/or has one or two appropriate transport amenities, which may include: covered walkways connecting the building entrances to transport waiting areas, covered waiting areas for public utility vehicle (PUV), terminals for PUVs and Asian utility vehicles (AUVs), and stations for public transportation routes accessible to the users of the project.
LOTUS1.25–2.50Has a mass transit services within 400 or 800 m from the SFH.
References: [66,67,68,69,71,73].
Table 7. Description of the “proximity to amenities” indicator.
Table 7. Description of the “proximity to amenities” indicator.
Considered by: Influence (%)The Influence Percentage Is Obtained When the Urban Environment:
BREEAM0.58–1.56Provides at least four amenities in a proximity of 500 m from the SFH; and/or provides at least seven amenities in a proximity of 1000 m to the SFH.
LEED0.91–1.82Has 4–7, 8–11, or more than 12 uses within an 800 m walking distance from the building entrance.
BEST0.91–1.82Has at least four or eight facilities within a 500 m walking distance.
CASA0.91–2.73Has 4, 7, or 11 basic community resources within 500 m; and/or has 7, 11, or 14 basic community resources within 1 km; and/or has transport services with at least 30, 60, or 125 trips per day of the week within 1 km from the SFH.
GBI1.00–4.00Has three or six amenities within 750 m from the SFH; and/or has another three or six different amenities within 750 m from the SFH.
BERDE1.00–2.00Has 5–9 or 10 key establishments, within a 250-meter radius from the SFH.
Green Homes1.33Has at least five basic house-hold amenities within a walking distance of 1 km from the SFH.
LOTUS1.25Has at least five different types of basic services within a 0.5 km radius from the SFH.
References: [66,67,68,69,70,71,72,73].
Table 8. Description of the exclusive SHMCIRUEs between the SHRSs.
Table 8. Description of the exclusive SHMCIRUEs between the SHRSs.
IndicatorNMA: Influence (%) The Influence Percentage Is Obtained When the Urban Environment:
1. Carbon TechnologiesENE: 0.39Has the infrastructure to provide low- or zero-carbon energy sources for the SFH.
2. Internet ConnectivityENE: 1.00Has infrastructure with access to internet service.
3. Alternative Modes of TransportINN: 0.78Has two of the following options or alternative modes of transport: communal car-club, electric recharging stations, or cycle storage spaces.
4. Recycled AggregatesINN: 0.39Has the infrastructure for transporting recycled or secondary aggregate, with a distance lower than 30 km by road transport to the housing unit.
5. Compact DevelopmentLCT: 0.91–2.73Has a DU/hectare of buildable land ≥ 17, 30, or 50.
6. Construction Workers’ AmenitiesLCT: 0.50Has accommodation for construction workers and has adequate health and hygiene facilities for workers.
7. Heat Island EffectMAT: 1.00–2.00Provides any combination of the following strategies for 50% or 75% of the site hardscape (including sidewalks, courtyards, plazas, and parking lots): shade (within 5 years of occupancy), and/or paving materials with a solar reflectance index (SRI) of at least 29, and/or an open grid pavement system.
8. Non-Structural Building WallsMAT: 0.63–1.88Has infrastructure to extract, harvest, and manufacture 40%, 60%, or 80% of the non-structural walls of the SFH.
9. Flooring MaterialsMAT: 0.63–1.25Has infrastructure to extract, harvest, and manufacture 40% or 80% of flooring materials of the SFH.
10. Roofing MaterialsMAT: 0.63–1.25Has infrastructure to extract, harvest and manufacture 40% or 80% of roofing materials of the SFH.
11. FurnitureMAT: 0.63–1.25Has infrastructure to extract, harvest, and manufacture 25% or 50% of all furniture items of the SFH.
12. Inclusive DesignTRA: 0.20Has communal or shared parking with spaces with a width of 3300 mm and maintains the distance from the public parking space to the dwelling entrance of ??? as a minimum, and is level or gently sloping.
13. Street NetworkTRA: 0.91Has high intersection density, defined as an area whose existing streets and sidewalks create at least 90 intersections per square kilometer.
14. Alternative Modes of TransportTRA: 0.78–1.56Has a communal-car club, where the members share the use of a locally based fleet of vehicles, and/or provides electric recharging stations for the SFH occupants (Table 35 in [67]).
15. CompostingWST: 0.78Has an accessible local communal or community composting service, run by either a local authority or a private organization; or has a management plan, which is in place to ensure food or green waste is appropriately removed and delivered to an alternative composting facility; or has a local authority, private organization, or green/kitchen waste collection system.
16. RecyclingWST: 0.39Has an established recyclable waste collection scheme.
References: [67,69,71,73].
Table 9. SHMCIRUEs considered by two SHRSs.
Table 9. SHMCIRUEs considered by two SHRSs.
IndicatorConsidered by: Influence (%) VariationsMost Rigorous
1. InnovationLEED: 0.91, CASA: 0.91–3.641LEED and CASA
2. Exemplary PerformanceLEED: 0.91, CASA: 0.911LEED and CASA
3. Social PracticesBREEAM: 0.16–0.49, CASA: 0.16–0.452BREEAM
4. Infill DevelopmentLEED: 1.82, CASA: 0.91–1.822LEED
5. Open SpaceLEED: 0.91, CASA: 0.912LEED
6. Regional PriorityLEED: 0.91–1.82, CASA: 0.452LEED
7. Construction NoiseBEST: 1.82, LOTUS: 1.252LOTUS
8. Health and WellnessCASA: 0.45, BEST: 1.822BEST
9. Recycled AggregatesBREEAM: 0.39, BEST: 0.452BEST
10. Building StructureLEED: 0.23–0.68, LOTUS: 0.63–1.882LOTUS
11. Windows and DoorsLEED: 0.23–0.68, LOTUS: 0.63–1.252LOTUS
12. Cycling NetworkLEED: 0.91, GBI: 1.00–2.002LEED
13. Construction and Demolition WasteCASA: 0.23–0.68, LOTUS: 0.502CASA
References: [67,68,69,70,73].
Table 10. SHMCIRUEs considered by three and five SHRSs.
Table 10. SHMCIRUEs considered by three and five SHRSs.
IndicatorConsidered by: Influence (%) VariationsMost Rigorous Least Rigorous
1. Renewable EnergyBEST: 0.45–1.36, CASA: 0.45–1.82, BERDE: 1.002BEST and CASABERDE
2. Local MaterialsBEST: 0.91–1.82, CASA: 0.45%, GBI: 0.50–1.00, BERDE: 0.50–1.50, Green Homes: 0.67–1.335BESTGreen Homes
3. Cycling AmenitiesBREEAM: 0.78–1.56, LEED: 0.91, BERDE: 1.00–2.002BERDEBREEAM
4. SecurityBEST: 0.91-1.82, CASA: 0.91–1.82, LOTUS: 0.942BEST CASA
5. Walkable StreetBEST: 0.91, CASA: 0.91–1.82, GBI: 1.00–2.002LEED CASA
References: [66,67,68,69,70,71,72,73].

Share and Cite

MDPI and ACS Style

Saldaña-Márquez, H.; Gámez-García, D.C.; Gómez-Soberón, J.M.; Arredondo-Rea, S.P.; Corral-Higuera, R.; Gómez-Soberón, M.C. Housing Indicators for Sustainable Cities in Middle-Income Countries through the Residential Urban Environment Recognized Using Single-Family Housing Rating Systems. Sustainability 2019, 11, 4276. https://doi.org/10.3390/su11164276

AMA Style

Saldaña-Márquez H, Gámez-García DC, Gómez-Soberón JM, Arredondo-Rea SP, Corral-Higuera R, Gómez-Soberón MC. Housing Indicators for Sustainable Cities in Middle-Income Countries through the Residential Urban Environment Recognized Using Single-Family Housing Rating Systems. Sustainability. 2019; 11(16):4276. https://doi.org/10.3390/su11164276

Chicago/Turabian Style

Saldaña-Márquez, Héctor, Diana C. Gámez-García, José M. Gómez-Soberón, Susana P. Arredondo-Rea, Ramón Corral-Higuera, and María C. Gómez-Soberón. 2019. "Housing Indicators for Sustainable Cities in Middle-Income Countries through the Residential Urban Environment Recognized Using Single-Family Housing Rating Systems" Sustainability 11, no. 16: 4276. https://doi.org/10.3390/su11164276

APA Style

Saldaña-Márquez, H., Gámez-García, D. C., Gómez-Soberón, J. M., Arredondo-Rea, S. P., Corral-Higuera, R., & Gómez-Soberón, M. C. (2019). Housing Indicators for Sustainable Cities in Middle-Income Countries through the Residential Urban Environment Recognized Using Single-Family Housing Rating Systems. Sustainability, 11(16), 4276. https://doi.org/10.3390/su11164276

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop