Design impact measures

Design impact measures are measures used to qualify projects for various environmental rating systems and to guide both design and regulatory decisions from beginning to end. Some systems, like the greenhouse gas inventory, are required globally for all business decisions. Some are project-specific, like the LEED point rating system which is used only for its own ratings, and its qualifications do not correspond to much beyond physical measurements.^{[citation needed]} Others like the Athena life-cycle impact assessment tool attempt to add up all the kinds of measurable impacts of all parts of a building throughout its life and are quite rigorous and complex.

The general field involves tying together environmental impact assessment and environmental accounting with systems ecology, cost estimation models, and cost–benefit analysis.^{[citation needed]}

Though sustainable design has existed since 2008,^{[citation needed]} the number and types of methods and resources that have become available since then has grown significantly. Many of these tools are preliminary guides to thinking about the complex processes of sustainable design in projects. As designers confront the impact of construction projects on the larger scale of human interaction with the earth, the problem of sustainable physical design grows increasingly complex and difficult.

Design impact measures are often used in DPSIR indicator models. As described in following sections of this page, there are many tools which help with data collection and impact measurements; however, without a framework within which to use these metrics, it is often difficult to make sense of them. The DPSIR indicator model provides this framework, which enables the proper presentation of the indicators required for various decision making or policy making. Establishing a proper and accurate DPSIR framework for specific environmental systems is a complex task.^[1]

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Quantitative researchers measure variables to answer their research question. The level of measurement that is used to measure a variable has a significant impact on the type of tests researchers can do with their data and therefore the conclusions they can come to. The higher the level of measurement the more statistical tests that can be run with the data. That is why it is best to use the highest level of measurement possible when collecting information. In this video nominal, ordinal, interval and ratio levels of data will be described in order from the lowest level to the highest level of measurement. By the end of this video you should be able to identify the level of measurement being used in a study. You will also be familiar with types of tests that can be done with each level. To remember these levels of measurement in order use the acronym NOIR or noir. The level of measurement of a variable depends on the nature of that variable as well as how the researcher collects the data. For example, some variables like gender can only be measured in a nominal way. Other variables like household income can be measured at multiple levels depending on how the question is asked. The nominal level of measurement is the lowest level. Variables in a study are placed into mutually exclusive categories. Each category has a criteria that a variable either has or does not have. There is no natural order to these categories. The categories may be assigned numbers but the numbers have no meaning because they are simply labels. For example, if we categorize people by hair color people with brown hair do not have more or less of this characteristic than those with blonde hair. Nominal sounds like name so it is easy to remember that at a nominal level you are simply naming categories. Nominal data may be considered dichotomous or categorical. Dichotomous data falls into one of two categories like Male/female or yes/no. Categorical data have more than two possible values such as marital status or group membership. Sometimes researchers refer to nominal data as categorical or qualitative because it is not numerical. Since nominal data is simply categorical it allows for the fewest statistical tests. It makes sense to report the number or percentage of people who are male or female in a particular group. This data is often presented in bar or pie charts. The only measure of central tendency that makes sense with nominal data is the mode. Many other statistical tests just do not make sense for nominal data. For example, since there is no natural way to order nominal data you cannot find a median or middle number. Likewise, you cannot calculate a mean gender since no numerical value for the data exists. Ordinal data is also considered categorical. The difference between nominal and ordinal data is that the categories have a natural order to them. You can remember that because ordinal sounds like order. Numbers are assigned to categories but they are arbitrary -- They are simply used to establish a ranking and there is no absolute zero. While there is an order, it is also unknown how much distance is between each category. The intervals between each number are therefore not necessarily equal. Ordinal scales are often used to measure attitudes and perceptions. For example, a survey may ask how satisfied a customer is on a scale from very dissatisfied to very satisfied. Nurses often use an ordinal scale to get patients to rank their pain on a scale from 1 to 10. This data is ordinal since it is unknown whether the intervals between each value are equal. On a 10 point scale, the difference between a 9 and a 10 is not necessarily perceived to be the same as the difference between a 3 and a 4. All we know is that if the patient rates their pain as an 8 now and a 4 after receiving pain medication the pain has decreased. We cannot accurately measure how much the pain has decreased since we do not know the difference between the points on the scale. It would be inaccurate to claim that the patient was in twice as much pain before receiving the medication. Likewise you cannot say that one patient is in twice as much pain as another using this scale. Remember that the values in an ordinal scale simply express an order. All nominal level tests can be run on ordinal data. Since there is an order to the categories the numbers assigned to each category can be compared in limited ways beyond nominal level tests. It is possible to say that members of one category have more of something than the members of a lower ranked category. However, you do not know how much more of that thing they have because the difference cannot be measured. To determine central tendency the categories can be placed in order and a median can now be calculated in addition to the mode. Since the distance between each category cannot be measured the types of statistical tests that can be used on this data are still quite limited. For example, the mean or average of ordinal data cannot be calculated because the difference between values on the scale is not known. Interval level data is ordered like ordinal data but the intervals between each value are known and equal. Therefore, the difference between two values is meaningful for interval variables. The zero point is arbitrary since a score of zero does not actually mean that the variable does not exist. Zero simply represents an additional point of measurement. For example, tests in school are interval level measurements of student knowledge. If you scored a zero on a math test it does not mean you have no knowledge. Yet, the difference between a 79 and 80 on the test is measurable and equal to the difference between an 80 and an 81. Temperature if measured in degrees Fahrenheit or Celsius is another good example of interval measurement. On the Fahrenheit scale the difference between a temperature of 37 degrees and 38 degrees is the same difference as between 89 degrees and 90 degrees. The 0 is arbitrary since a temperature of 0 degrees does not mean that there is no temperature. With interval level scales there is direct, measurable quantity. In addition, zero does not represent the absolute lowest value. Instead, it is point on the scale with numbers both above and below it. If you know that the word interval means space in between it makes remembering what makes this level of measurement different easy. Interval scales not only tell us about order, but also about the value between items on a scale. Since the distance between points on the scale is measurable and equally split it is possible to do more statistical tests with the data. The mean, median and mode can all be calculated with interval data. The standard deviation can also now be calculated. However, the problem with performing statistical tests on interval scales is that they don't have a "true zero." Therefore it is impossible to multiply, divide or calculate ratios. Ratio measurement is the highest level possible for data. Like interval data, Ratio data is ordered, with known and measurable intervals between each value. What differentiates it from interval level data is that the zero is absolute. The zero occurs naturally and signifies the absence of the characteristic being measured. Remember that Ratio ends in an o therefore there is a zero. Typically this level of measurement is only possible with physical measurements like height, weight and length. Any statistical tests can be used with ratio level data as long as it fits with the study question and design. It is possible to compare amounts of the variable and make a claim that one is twice as much as the other. Remember that when working with ratio variables, but not interval variables, you can look at the ratio of two measurements. Remembering the basic differences can help you remember the levels of measurement. Nominal is named. Ordinal is ordered. Interval has a known interval or difference. Ratio has a true zero. To decide what level of measurement a particular variable is ask yourself these questions in order: First, Is the variable ordered? If not, the variable is nominal. If it is ordered, ask yourself if there are equal distances between values. If not, the variable is ordinal. If values are equally spaced, ask yourself If a value of zero actually means that the variable being measured does not exist. If not, the variable is interval. If zero does mean none, the variable is ratio because the zero is absolute. The level of measurement dictates the appropriate statistical tests that can be used. One of the reasons for learning about levels of measurement is so you know what statistical tests can be performed on different types of data. That way you can avoid making mistakes in your own work and critique the work of others. Be aware that Some people gather ordinal level data and treat it like interval data once numbers are assigned to it. Researchers need to be careful not to make interval and ratio claims about ordinal data. Be careful not to claim that something is twice as much as something else if the data were not collected at the appropriate level. Classifications of some forms of data are debated. For example, some researchers treat the measurement of intelligence as ordinal while others treat it as interval. Likewise, money in a bank account may be considered ratio since having a balance of 0 means you don't have any money. However, others argue it is interval since it is possible to have a negative balance, which makes the 0 point simply another point of measurement. So, what level do you think it is? Can you think of any other controversial examples? Comment below to start a discussion. What is important to know when reviewing an article is how the data was collected so you can identify if the appropriate statistical tests were used to analyze the data. If you are doing research try to collect data in the highest form possible so a wider variety of tests can be preformed on it. Sometimes how you ask the question will determine what level your data is at. Knowing the level of measurement for your data will help you avoid mistakes like taking the average of people's marital status. To help you remember what you need to know about the levels of measurement try making a simple study table to include in your notes. It is helpful to include an example in the chart that will help you remember each level. For more you can check out some of my related videos or website. You are also welcome to subscribe for regular updates. If there is something specific you are looking for or would like created please comment and let me know. Thank you for watching.

Simple Online Calculators

Simple online calculators allow users to estimate their individual environmental impact. The use of these calculators contribute to three main goals:^[2]

Increase awareness about individual environmental impact
Promote changes in behavior to reduce environmental impact
Facilitate discussions around sustainability

There exist various types of online calculators that assess impacts related to Materials, Energy, Greenhouse Gas, Water, Solid Waste, Ecosystem, Pollutants, and more.^[3] The generally accepted way that these online tools calculate the impacts is:

Request user input data
Use the data provided in conjunction with Life Cycle Assessment (LCA) data to generate the impact results
Compile and share the results with the user

The Energy Star building energy calculator and targeting tool is based on data from the United States International Energy Agency (US IEA) and Commercial Buildings Energy Consumption Survey (CBECS), which records long-term US nationwide energy use. Projects seeking for a Green Globes rating would use this calculator.

Another simple calculator that is available online is the "Build Carbon Neutral" calculator and, for UK users, the "Footprinter". These tools estimate a building's total carbon footprint by calculating easily visible parts, namely total surface area, building height, and ecoregion.

Design Impact Measures for Buildings

Recently, there has been a transition to focus on the environmental impacts of buildings. Green Building is described by the US EPA as "Green building is the practice of creating structures and using processes that are environmentally responsible and resource-efficient throughout a building's life-cycle from siting to design, construction, operation, maintenance, renovation and deconstruction. This practice expands and complements the classical building design concerns of economy, utility, durability, and comfort.".^[4] The role of design impact measures for buildings is to assess the impacts of a building and identify opportunities for improvement. Simulation tools exist to optimize building systems. Some common impact measure categories are:

Energy Consumption
Water Consumption
Material Use
Recyclability of Materials
Air Quality
Water Quality
Land and Soil Quality
Virgin Resource Depletion
Biodiversity and Habitat Loss
Occupant and Worker Health
Longevity of Building

These metrics categories assess the impacts of buildings and allow the identification of areas for improvement. Metrics are used in Ratings Systems, Standards, and Building Codes; some common ones are:

The common strategies for success across rating systems, standards, and building codes are:

Reduce Building Demand
Harvest Site Energy
Maximize Building Efficiency and Resiliency
Optimize Building Commissioning
Optimize ongoing Operations and Maintenance

Other than the rating systems, standards, and building codes listed above, software platforms have been developed to facility the measurement, collection and aggregation, and comparison of these metrics. These platforms aid companies, within the building industry, track impact data and communicate goals and achievements. Some of these platforms are:

"Athena Eco-Calculator": this calculator is an advanced and thorough life-cycle impact assessment tool for buildings
"Arc Skoru Tool": this LEED-specific tool enables users to streamline data collection, generate impact scores, assess/improve impacts using modeling, and communicate key performance indicators
"Measurabl": this ESG platform is an easily accessible all-in-one sustainability hub that enables users to measure, manage, disclose, and act on sustainability data

Advanced Impact and Energy Analysis Tools

The United States Department of Energy (USDOE) offers a list of building energy tools for designers. While it is extensive, it may still be incomplete as new innovative tools are created. However, it contains a lot of resources for designers to begin with.

Other advanced analysis tools include:

The "Greenhouse gas protocol": this is an intergovernmental data service used by the major international bodies for organizing the greenhouse gas data and reporting requirements. The protocols are organized by industry.
The "EcoFootprint": this is a method of measuring a building's total use of productive land, or its ecological footprint. It uses data from studies indicating that human burden on renewable resources is significantly greater than the Earth's regenerative capacities.^{[citation needed]} The results may not measure uncertainty, but it offers a comparable dimension

Recently, existing and emerging design and engineering software packages are also incorporating energy impact tools and climate modeling tools into their software.^{[citation needed]} Many of them rely on the move to Building information modeling (BIM) data models that allow many consultants to work on the same building or urban design scheme at once.

References

^ "Driver-Pressure-State-Impact-Response Framework (DPSIR)". www.fao.org. Archived from the original on 2017-11-21. Retrieved 2021-12-15.
^ Kok, Anne Linda; Barendregt, Wolmet (2021-12-01). "Understanding the adoption, use, and effects of ecological footprint calculators among Dutch citizens". Journal of Cleaner Production. 326: 129341. doi:10.1016/j.jclepro.2021.129341. ISSN 0959-6526. S2CID 239185524.
^ "Paper Calculator 4.0 | Environmental Paper Network". c.environmentalpaper.org. Retrieved 2021-12-10.
^ "Basic Information | Green Building |US EPA". archive.epa.gov. Retrieved 2021-12-10.

This page was last edited on 12 February 2023, at 15:23

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