Term
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Definition
Links organization with its marketing environment; involves specification, gathering, analysis, and interpretation of info to help management understand the environment, identify problems and opportunities, and develop and evaluate courses of action |
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Term
3 C's (Framework for Marketing Strategy |
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Definition
Analyze situation for customer, company, and competitor |
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Term
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Definition
Segmentation -> Targeting -> Positioning (Set Strategy) |
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Term
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Definition
Product, Price, Promotion, Place (Formulate tactical plan for each) |
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Term
Uncontrollable Environmental Factors |
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Definition
Economy Technology Laws & Regulations Social & Cultural Factors Political Factors |
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Term
Controllable Marketing Variables |
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Definition
Product Pricing Promotion Distribution |
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Term
Heinz Ketchup in Brazil (example) |
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Definition
Heinz wanted to use learning from Mexico where it was successfully launched (focused on making the product available in neighborhood stores in Mexico). However, in Brazil, most grocery shopping is done in supermarkets |
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Term
Coca-Cola in India (example) |
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Definition
In the U.S., people consume soft-drinks with meals, but in India people mostly drank water with meals. Their brand proposition was to "enhance the moments we already enjoy everyday" through coke. |
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Term
First step in the Market Research Process |
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Definition
Define research problems (decisions/assumptions, and the inputs needed) |
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Term
Second step in the Market Research Process |
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Definition
Identify research design (Needs should drive design--subject to logistics) |
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Term
Third step in the Market Research Process |
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Definition
Measurement (useful data comes from good communication) |
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Term
Fourth step in the Market Research Process |
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Definition
Sampling (who can give us the needed answers?) |
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Term
Fifth step in the Market Research Process |
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Definition
Analysis (what can we learn) |
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Term
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Definition
-Determine the basis of segmentation -Establish market potential and responsiveness for various segments -Select target markets -Create lifestyle profiles: demography, media, and product image characteristics |
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Term
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Definition
-Test concept -Determine optimal product design -Package tests -Brand positioning and repositioning -Test marketing |
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Term
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Definition
-Pricing policies -Importance of price in brand selection -Product line pricing -Price elasticity of demand |
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Term
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Definition
-Copy decisions -Media decisions -Creative advertising testing -Optimal promotional budget -Optimal promotional mix -Evaluation of advertising effectivess |
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Term
Way marketing research can go wrong: |
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Definition
-asking the wrong research question -drawing conclusions from unrepresentative (potentially small) samples ( issue with generalization_) -Uncontrollable Environment Factors |
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Term
Ethical issues in field work |
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Definition
Increasing discomfort level of respondents (misleading respondents, disrespecting their privacy)
-Following unacceptable field work procedures (inappropriate sampling procedures and sample size) |
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Term
Ethical issues in data preparation and analysis |
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Definition
Identifying and discarding unsatisfactory respondents
Using questionable statistical techniques |
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Term
Ethical issues in interpreting results |
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Definition
making incorrect conclusions and recommendations
incomplete or biased reporting |
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Term
Research is valuable if it is: |
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Definition
-Relevant -Timely -Accurate -Cost effective -Designed with decision goals in mind |
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Term
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Definition
-Can reduce, but not eliminate uncertainty -Does not replace decision making -Pay careful attention to the assumptions |
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Term
What makes the quality control scenario "ideal"? |
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Definition
-Random selection of items to inspect (how can selection of items to inspect be "biased"?)
-Population clearly known (We know in which "world" our statistical inferences hold)
-Errors (or deviations from the standard) follow a well-defined pattern |
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Term
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Definition
Can be tabulated in a Frequency Table and put into a data distribution bar graph |
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Term
What do we use for continuous data? |
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Definition
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Term
Normal Distribution (Gaussian) |
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Definition
A mathematical ideal that extends from negative infinity to positive infinity. The Y-axis is a probability (Probability density curve). Center line is mu, each segment is a standard deviation from mu (the mean). |
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Term
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Definition
used to describe the basic features of data; ex: central tendency (typical value, e.g. mean, median mode), dispersion (how much "spread" around typical, e.g. a standard deviation), skewness |
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Term
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Definition
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Term
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Definition
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Term
[image]
What is the circled number? |
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Definition
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Term
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Definition
Current state of the world (status quo) |
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Term
Alternative/Experimental Hypothesis (H1) |
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Definition
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Term
What is a two-tailed test? |
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Definition
A test in which the alternative hypothesis (your hypothesis) is that the actual state of the world is higher or lower than the null hypothesis (status quo). [image] |
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Term
What is a one-tailed test? |
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Definition
The alternative hypothesis (your hypothesis) is that the actual state of affairs is EITHER higher or lower than the status quo (null hypothesis). >, < |
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Term
What do we use to "feel good" about our decision and feel confident that the new value is either part of the old null distribution or actually part of a new distribution of IQ scores? |
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Definition
Significance level (alpha) |
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Term
Significance Level (alpha) |
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Definition
How far in the NULL distribution are you willing to go to be confident that an observed value DOES NOT belong to the NULL distribution---> typically alpha = 0.05 or 5% |
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Term
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Definition
Value at green bar belongs to the alternative distribution. This means we must UPDATE our knowledge of the current state of the world |
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Term
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Definition
Value at green bar belongs to the NULL hypothesis; thus we didn't learn anything new |
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Term
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Definition
1. Right decision (Accept null, when null is true)
2. Type 2 Error (accept null when alternative is true)
3. Type 1 error (reject null when null is true)
4. Right decision (reject null when alternative is true) |
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Term
The Marketing Research Process for PRIMARY Research |
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Definition
1. Identify a business problem 2. Translate problem into a research methodology 3. Design the research instrument e.g., surveys, questionnaires, or guidelines 4. Sampling plan 5. Data collection and coding 6. Analysis, interpretation and reporting |
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Term
In the first step of the Market Research Process we first identify the __________ problem, and then formulate the ___________problem. |
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Definition
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Term
Potential Marketing Problems of Declining Market Share |
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Definition
-Outdated product -New competition -Shifting demographics -Inappropriate pricing |
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Term
Potential Marketing Problems of Declining Profits |
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Definition
-Ineffective promotions -Escalating distribution costs -Improper channel structure |
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Term
Potential Marketing Problems of Inability to Gain Channel Participation |
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Definition
-Lack of product differentiation -Misdirected promotions -Inferior product image |
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Term
Potential Marketing Problems of Heavy Turnover in Sales Force |
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Definition
-Lack of proper sales incentives -Improper allocation of territories -Unrealistic sales quotes |
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Term
Potential Marketing Problems of Declining Company Sales |
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Definition
-Decline in industry sales -Increased competition |
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Term
Goal of Marketing Research |
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Definition
to provide relevant, accurate, reliable, valid, and current information to facilitate managerial decisions |
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Term
What are methods to performing exploratory research? |
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Definition
In-depth interviews, focus group discussions, observational studies |
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Term
What are some characteristics of exploratory research? |
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Definition
Flexible, versatile, but not conclusive |
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Term
What is exploratory research useful for? |
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Definition
Discovery of ideas and insights |
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Term
What are methods to performing descriptive research? |
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Definition
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Term
What are characteristics of descriptive research? |
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Definition
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Term
What is descriptive research useful for? |
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Definition
Describing opinions, attitude and market characteristics |
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Term
What are methods to performing causal research? |
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Definition
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Term
What are some characteristics of causal research? |
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Definition
Treatment and Control (A/B) |
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Term
What is causal research useful for? |
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Definition
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Term
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Definition
1. Exploratory Research Design 2. Conclusive Research Design |
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Term
What are the two types of research that fall under the conclusive research design |
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Definition
Descriptive Research, Causal Research |
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Term
What are the two types of research design methods that fall under Descriptive Research? |
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Definition
Cross-Sectional, and Longitudinal |
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Term
What are the two types of Cross-Sectional Research designs? |
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Definition
Single cross-sectional design, multiple cross-sectional design |
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Term
Uses of exploratory research |
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Definition
Formulate a problem or define a problem more precisely, identify alternative courses of action, develop hypotheses, isolate key variables and relationships for further examination, and establish priorities for further research (often done before CONCLUSIVE/formal/quantitative research is undertaken) |
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Term
What is the objective of Qualitative Research? |
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Definition
To gain qualitative understanding of the underlying reasons and motivations |
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Term
What does a typical sample for Qualitative Research look like? |
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Definition
Small number of cases; often non-representative |
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Term
What kind of data collection occurs in qualitative research? |
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Definition
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Term
What kind of data analysis do we perform when observing qualitative research? |
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Definition
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Term
What is the outcome of qualitative research? |
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Definition
Develop an initial understanding (often) |
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Term
What is the objective of Quantitative Research? |
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Definition
To quantify the data and generalize the results from the sample to the population of interest |
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Term
What does a typical sample for Quantitative Research look like? |
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Definition
Large number of cases; often representative |
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Term
What kind of data collection occurs in quantitative research? |
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Definition
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Term
What kind of data analysis do we perform when observing quantitative research? |
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Definition
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Term
What is the outcome of quantitative research? |
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Definition
Recommend a final course of action (often) |
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Term
Methods of exploratory research |
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Definition
Focus groups, depth interviews, observation studies, lead user analysis ("beta testing") |
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Term
When setting up a focus group to perform exploratory research, what should we do in terms of recruitment for the study? |
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Definition
Screen participants on qualifications, demographics, and segments |
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Term
What should be set up before staging a focus group? |
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Definition
Hosting multiple sessions, and having a moderator provide a loose outline of the session and prioritize questions |
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Term
How should a focus group typically flow? |
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Definition
1. Introduction (set the tone, no right/wrong answers, videotaping, two-way mirror, clients interested in research, controlled but informal)
2. Controlling the session (everyone participates within reason, safe for all points of view)
3. Problem respondents are handled discreetly ("Phone call for you, please take all of your things") |
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Term
Focus Groups produce ______(quantitative/qualitative)___ data. |
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Definition
Qualitative, provides a consensus around major "trends", "Verbatims" often are used to substantiate future business recommendations, but NEVER quantify the data gathered. (i.e. NEVER try to set up an "x% of participants" conclusion) |
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Term
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Definition
an unstructured, indirect form of questioning that encourages respondents to project their underlying motivations, beliefs, attitudes or feelings regarding the issues of concern. |
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Term
Common techniques used in qualitative research? |
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Definition
-Projection -Word association -Sentence Completion (and paragraph/story completion) -Picture interpretation (ZMET, Zaltman Metaphor Elicitation Technique) |
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Term
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Definition
respondents are presented with a list of words, one at a time, and asked to respond to each with the first word that comes to mind. The words of interest, called test words, are interspersed throughout the list which also contains some neutral, or filler words to disguise the purpose of the study. Responses are analyzed by calculating the frequency with which any word is given as a response, the amount of time that elapses before a response is given. |
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Term
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Definition
Sample word association results |
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Term
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Definition
respondents are given incomplete sentences and asked to complete them. Generally, they are asked to use the first word of phrase that comes to mind. (Ex. "A person who shops at Sears is __________________.") |
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Term
ZMET (Zaltman Metaphor Elicitation Technique) |
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Definition
Participants are asked to bring pictures that they think represents a particular topic (e.g. a brand) to the interview (gives participants control of the research stimuli and a greater sense of involvement with the interview topic). The pictures are metaphors that serve as entry points into their thinking process. Exploring the meaning of these metaphors (by a trained interviewer) allows us to elicit many important ideas. |
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Term
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Definition
Interviewing professional respondents, with scheduled interviews, at a lower cost than Focus Group discussions. However, less information is found through these discussions. |
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Term
What is the technique used in depth interviews in which the line of questioning proceeds from product characteristics to user characteristics, allowing the researcher to tap into the consumer's network of meanings? Example? |
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Definition
Laddering
1. "Finished homework" - product characteristics
2. "So I can do well in school"
3. "So I can get a good job"
4. "So I won't be homeless"
Advertising theme for getting homework done: not being homeless --> "Get shit done. Don't have to shit outside." |
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Term
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Definition
Observe customers in their native surroundings to understand unarticulated needs. Works best when developers are proposing solutions for an identified potential user population, whose needs are poorly understood. |
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Term
What are some issues researchers are faced with when performing observation studies? |
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Definition
What is the "data"?
Transparency to "participants" |
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Term
Disadvantages of qualitative techniques. |
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Definition
-Respondent fatigue (except observation studies) -Serious risk of interpretation bias -Requires trained interviewer -Could be expensive |
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Term
Advantages of qualitative techniques |
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Definition
-Starting point of more structured quantitative research -Useful for intimate product categories like cosmetics, luxury undergarments. (uncover feelings, beliefs, values, and attitude) |
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Term
When do we use descriptive research? |
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Definition
1. To describe the characteristics of relevant groups such as consumers, salespeople, organizations, or market areas
2. To estimate the percentage of units in a specified population exhibiting a certain behavior
3. To determine the perceptions of product characteristics
4. To determine the degree to which marketing variables are associated (relational statistics, e.g., correlation) |
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Term
What are the four main types of survey methods? |
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Definition
Telephone, personal, mail, electronic |
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Term
Factors for evaluating usefulness of survey methods (e.g. personal vs. email) |
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Definition
1. Response rate(% of total attempted interviews completed)
2. Sample control: ability to reach the sample members effectively and efficiently
3. Control of data collection environment: the environment in which the respondent answers questions (includes control over field staff and supervisors)
4. Respondent factors: perceived anonymity and social desirability
5. Diversity of question types / stimuli that can be used |
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Term
Method of getting a random sample of phone interview participants |
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Definition
Select an area code (target market), replace the last three digits with a random number generated between 000 and 999, and repeat the process until the desired number of telephone numbers is obtained |
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Term
Single Cross-Sectional Design |
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Definition
only one sample of respondents and info is obtained from this sample only once |
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Term
Multiple Cross-Sectional Design |
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Definition
two or more samples of respondents and info from each sample is obtained only once |
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Term
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Definition
A fixed sample of population elements is measured repeatedly on the same variables |
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Term
What is the difference between Longitudinal and Cross-Sectional designs? |
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Definition
Longitudinal design sample or samples remain the same over time |
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Term
Which type of descriptive research is better at detective change? |
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Definition
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Term
What type of descriptive research is more accurate? |
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Definition
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Term
What type of descriptive research is better at preventing response bias? |
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Definition
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Term
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Definition
companies that collect and sell common pools of data of known commercial value designed to serve a number of clients (Ex. Nielsen Media Panel, Scanner Data); Includes sources from both consumers and institutions such as retailers, wholesalers, and/or industrial firms. |
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Term
What is the Nielsen Media Panel? |
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Definition
11,000 U.S. household are randomly selected and a "Nielsen People Meter" is placed on each TV in the household. Their tuning data is stored in the PM and automatically uploaded to Nielsen servers each night. This allows Nielsen to estimate TV viewing by demographic and socioeconomic characteristics like household income, education of head of house, occupation of head of house, household size, age of children, age of women, and geographic location, etc.. |
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Term
What are the two major types of errors that can go wrong in descriptive research? |
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Definition
Random/Sampling Error, Non-Sampling Errors |
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Term
What are the two major types of non-sampling errors that can occur during descriptive research? |
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Definition
Response Error and Non-Response Error |
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Term
What are the three major reasons for a response error in descriptive research? |
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Definition
Researcher error: Measurement error, population definition error, sampling frame error, data analysis error
Interviewer Error: Respondent selection error, questioning error, recording error, cheating error
Respondent Error: Inability Error, unwillingness error |
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Term
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Definition
Descriptive research error due to the particular sample selected being an imperfect representation of the population of interest.
Error is defined as the variation between the true mean value for the sample and the true mean value of the population. |
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Term
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Definition
Due to various reasons such as errors in the problem definition, approach, scales, questionnaire design, interviewing methods, and data preparation and analysis. Results in non-response/bad response errors. |
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Term
An increase in sample size (decreases/increases) random error, but also (increases/decreases) the non-sampling error. |
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Definition
Increase in sample size decreases random error (if considerable size from relevant population is taken), but also increases the non-sampling error. |
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Term
Describe the Concept of Causality |
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Definition
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Term
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Definition
Concomitant Variation Time Order of Occurrence Absence of Other Possible Causal Factors |
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Term
Concomitant Variation (Conditions for Causality) |
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Definition
extent to which a cause, X, and an effect, Y, occur together or vary together in the way predicted by the hypothesis under consideration |
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Term
Time Order of Occurrence (Conditions for Causality) |
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Definition
states that the causing event must occur either before or simultaneously with the effect; it CANNOT occur afterwards. |
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Term
Absence of Other Possible Causal Factors (Conditions for Causality) |
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Definition
the factor or variable being investigated should be the only possible causal explanation. |
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Term
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Definition
Getting the same result if measured again |
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Term
Internal validity (Causality) |
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Definition
Measuring exactly what you think you're measuring.
Refers to whether the manipulation of the independent variables or treatments actually caused the observed effects on the dependent variables; Control of extraneous variables is a necessary condition for establishing internal validity |
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Term
External Validity (Causality) |
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Definition
Can I generalize the result?
Refers to whether the cause-and-effect relationships found in the experiment can be generalized. (To what populations, settings, and times can the results be projected?) |
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Term
Limitations of Experimentation |
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Definition
1. Experiments can be time consuming to design 2. Experiments are often expensive (businesses often look at the control group as a "waste") 3. Experiments can be difficult to administer. (Can be impossible to control for the effects of the extraneous variables, particularly in a field environment) |
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Term
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Definition
1. Laboratory/Survey 2. Field |
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Term
Research Instrument (3rd Step of Marketing Research Process for Primary Research) |
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Definition
a testing device for measuring a given phenomenon, such as a paper and pencil test, a questionnaire, an interview, a research tool, or a set of guidelines for observation |
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Term
Measurement (Part of 3rd step of Marketing Research Process for Primary Research) |
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Definition
assigning numbers to characteristics. Must follow some rules which would be standardized and applied uniformly, and not change over objects or time. Measurement is fundamental in all branches of science, both social (e.g. Economics) and natural (e.g. Physics) |
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Term
Examples of difficult things to measure |
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Definition
Attitude, perception, and satisfaction |
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Term
Examples of things than can be easily measured |
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Definition
GDP of a country, unemployment rate of a country in a quarter, height of a student, time taken to complete a 200m race |
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Term
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Definition
branch of measurement that involves the construction of an instrument that associates qualitative constructs with quantitative metric units.
Types of Scaling: Nominal, Ordinal, Interval, Ratio |
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Term
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Definition
Nominal, Ordinal, Interval, Ratio |
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Term
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Definition
Numbers serve only as labels or tags for identifying and classifying objects
Only permissible operation is counting
Example: Meal Preferences can be 1-Breakfast 2-Lunch 3-Dinner |
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Term
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Definition
"Ranking"
**OFTEN INTERPRETED AS INTERVAL DATA FOR THE SAKE OF RESEARCH BY ASSUMING EQUAL INTERVALS
Can determine whether an object has more or less of a characteristic than some other object, BUT NOT HOW MUCH MORE OR LESS.
Permissible operations are counting and statistics based on centiles, like percentile, quartile, median.
Example: Satisfaction of customers Low/Medium/High Customer 1: Low Customer 2: Low Customer 3: Low Customer 4: Medium Customer 5: High
Median is Customer 3's opinion: Low (must be in order to get median) Placement in a percentile: grouping them by what percentage of the participants stated greater than or equal satisfaction than a particular participant. |
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Term
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Definition
Numerically equal distances on the scale represent equal values in the characteristic being measured.
Permits comparison of the differences between objects.
The location of the zero point is not fixed. Both the zero point and the units of measurement are arbitrary. (0 Celsius does not mean presence of no heat, it is arbitrary)
It is not meaningful to take ratios of scale values.
Permissible operations: counting, statistics based on centiles, arithmetic mean, standard deviation, and other statistics commonly used in marketing research |
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Term
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Definition
Possesses all the properties of nominal, ordinal, and interval scales
ABSOLUTE ZERO POINT
Meaningful to compute RATIOS of scale values (can say "Twice as high, or one-half as much")
All statistical techniques can be applied to ratio data. |
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Term
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Definition
1. Nominal 2. Ordinal 3. Interval 4. Ratio |
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Term
What statistics methods should we use for the following example:
"1. When at home, which TV brand do you watch most often? (circle one)" __Sony __Toshiba __Panasonic __Samsung __Phillips __Other |
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Definition
Frequency tables, mode, percentages belonging to each group |
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Term
What statistics methods should we use for the following example, and what type of scale are we using?:
"1. Please rank each television brand in terms of your preference. Place a 1 by your top choice, 2 by second choice, etc. __Sony __Toshiba __Panasonic __Samsung __Phillips __Other " |
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Definition
Frequency tables, mode, median
Ranking-----> ORDINAL (X is better than Y but can't say by how much) |
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Term
What statistics methods should we use for the following example, and what type of scaling are we using here?:
"1. For each brand below, indicate how much you like each brand by circling the appropriate number:
1-Do Not Like at All 5- Like very much
Sony 1 2 3 4 5 Toshiba 1 2 3 4 5 Panasonic 1 2 3 4 5 " |
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Definition
Frequency tables, mode, median, mean, standard deviation
RATINGS ---> Interval scale, X is n units different from Y, distance between 2 and 3 is the same as distance between 3 and 4 (ideally) |
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Term
What statistics methods should we use for the following example and what type of scaling are we using?:
"1. How much would you be willing to pay for a 24" flat screen TV made by each company?
Sony $__________ Toshiba $_______ Panasonic $________" |
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Definition
Frequency tables, mode, median, mean, standard deviation, geometric mean
Absolute magnitude are meaningful
RATIO SCALE---> $0 IS ABSOLUTE ZERO, $40 IS TWICE AS MUCH AS $20, $20 IS HALF AS MUCH AS $40) |
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Term
|
Definition
Numbers serve only as labels or tags for identifying and classifying objects
Only permissible operation is counting
Example: Meal Preferences can be 1-Breakfast 2-Lunch 3-Dinner |
|
|
Term
|
Definition
"Ranking"
**OFTEN INTERPRETED AS INTERVAL DATA FOR THE SAKE OF RESEARCH BY ASSUMING EQUAL INTERVALS
Can determine whether an object has more or less of a characteristic than some other object, BUT NOT HOW MUCH MORE OR LESS.
Permissible operations are counting and statistics based on centiles, like percentile, quartile, median.
Example: Satisfaction of customers Low/Medium/High Customer 1: Low Customer 2: Low Customer 3: Low Customer 4: Medium Customer 5: High
Median is Customer 3's opinion: Low (must be in order to get median) Placement in a percentile: grouping them by what percentage of the participants stated greater than or equal satisfaction than a particular participant. |
|
|
Term
|
Definition
Numerically equal distances on the scale represent equal values in the characteristic being measured.
Permits comparison of the differences between objects.
The location of the zero point is not fixed. Both the zero point and the units of measurement are arbitrary. (0 Celsius does not mean presence of no heat, it is arbitrary)
It is not meaningful to take ratios of scale values.
Permissible operations: counting, statistics based on centiles, arithmetic mean, standard deviation, and other statistics commonly used in marketing research |
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|
Term
|
Definition
Possesses all the properties of nominal, ordinal, and interval scales
ABSOLUTE ZERO POINT
Meaningful to compute RATIOS of scale values (can say "Twice as high, or one-half as much")
All statistical techniques can be applied to ratio data. |
|
|
Term
|
Definition
1. Nominal 2. Ordinal 3. Interval 4. Ratio |
|
|
Term
What statistics methods should we use for the following example:
"1. When at home, which TV brand do you watch most often? (circle one)" __Sony __Toshiba __Panasonic __Samsung __Phillips __Other |
|
Definition
Frequency tables, mode, percentages belonging to each group |
|
|
Term
What statistics methods should we use for the following example, and what type of scale are we using?:
"1. Please rank each television brand in terms of your preference. Place a 1 by your top choice, 2 by second choice, etc. __Sony __Toshiba __Panasonic __Samsung __Phillips __Other " |
|
Definition
Frequency tables, mode, median
Ranking-----> ORDINAL (X is better than Y but can't say by how much) |
|
|
Term
What statistics methods should we use for the following example, and what type of scaling are we using here?:
"1. For each brand below, indicate how much you like each brand by circling the appropriate number:
1-Do Not Like at All 5- Like very much
Sony 1 2 3 4 5 Toshiba 1 2 3 4 5 Panasonic 1 2 3 4 5 " |
|
Definition
Frequency tables, mode, median, mean, standard deviation
RATINGS ---> Interval scale, X is n units different from Y, distance between 2 and 3 is the same as distance between 3 and 4 (ideally) |
|
|
Term
What statistics methods should we use for the following example and what type of scaling are we using?:
"1. How much would you be willing to pay for a 24" flat screen TV made by each company?
Sony $__________ Toshiba $_______ Panasonic $________" |
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Definition
Frequency tables, mode, median, mean, standard deviation, geometric mean
Absolute magnitude are meaningful
RATIO SCALE---> $0 IS ABSOLUTE ZERO, $40 IS TWICE AS MUCH AS $20, $20 IS HALF AS MUCH AS $40) |
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Scaling Techniques can be ________ and ______________. |
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Definition
Comparative, non-comparative |
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Definition
involve the direct comparison of stimulus objects (ex. two brands compared along quality dimension)
Comparative data must be interpreted in relative terms and have only ordinal or rank order properties. |
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Definition
each object is evaluated independently of the others in the stimulus set. (Ex. one brand is rated on a scale independent of other brands). Resulting data are generally assumed to be interval or ratio scaled |
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Definition
Paired Comparison Question |
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Advantages of Paired Comparison Questions |
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Definition
Same known reference points for all respondents
Easily understood and can be programmed in a survey (including validating *wrong* responses) |
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Disadvantages of Paired Comparison Questions |
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Definition
Ordinal nature of data (cannot say how much they prefer one over the other) Inability to generalize beyond the stimulus objects (They might have a preference for a product not listed in the columns/rows) |
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What is this? [image] [image] |
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Definition
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What is this? [image][image] |
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What types of comparative scaled questions are there? |
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Definition
Paired Comparison Rank Order Constant Sum |
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What are some types of non-comparative scaled questions? |
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Definition
Continuous Rating Questions/Sliders Itemized Rating Scale (Likert Scale, Semantic Differential Scale) |
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Term
Continuous Rating Questions/Sliders |
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Definition
Respondents rate the objects by placing a mark at the appropriate position on a line that runs from one extreme of the criterion variable to the other. Used in non-comparative scaling.
Ex. "How would you rate Sears as a department store?"
Probably The Worst 0 --------> Probably the Best 100 |
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Definition
The respondents are provided with a scale that has a number or brief description associated with each category. Categories are ordered in terms of scale position, and the respondents are required to select the specified category that best describes the object being rated. Commonly used itemized rating scales are the likert and semantic differential scales |
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Definition
requires the respondents to indicate a degree of agreement or disagreement with each of a series of statements about the stimulus objects. Analysis can be conducted on an item-by-item basis or total (summated) score can be calculated. Negative items with similar semantic meaning should be reverse coded when computing overall score.
[image] |
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Term
What can having odd scale-points on a Likert Scale do? |
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Definition
Allows participants to express indifference (but respondents might be tempted to not apply their mind and choose this) |
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Advantage of having fewer items on a Likert test |
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Definition
easier to process/interpret by respondents |
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Advantage of having more items on a Likert test |
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Definition
Respondents might be able to express minute differences in their answers |
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Term
What happens when we label all items in a Likert scale? |
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Definition
Consistent interpretation, but reads more ordinal-like than if we only labeled end points. |
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Definition
A type of itemized rating scale with end points associated with bipolar labels that have semantic meaning (usually the scale has 7 points)
Example:
Describe your mood-
Sad --:--:--:--:--:X:--: Happy |
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What strategy do we use to control the tendency of semantic differential respondents to mark right- or left-hand sides without reading labels? |
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Definition
Positioning negative adjective sometimes on the left, and sometimes on the right |
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Definition
Occurs when participants gauge probability based off of how often they personally are put in specific situations.
Ex. what is a more likely cause of death in the U.S.: being killed by falling airplane parts, or being killed by a shark? --> Chance of dying form falling airplane parts is 30x more likely than getting killed by a shark |
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Another word for "immediate exposures" that affect our attitude and perceptions. |
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Definition
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Enabling a person to discover or learn something for themselves. |
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Heuristics can lead to these types of biases: |
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Definition
Confirmation, False Consensus, and Fundamental Attribution Error |
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Definition
Remembering info that supports our beliefs |
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Thinking our own preferences represent the majority |
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Fundamental Attribution Error |
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Definition
Thinking other people's actions reveal their preferences/attitudes |
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Consider two different persons, Mr.A and Ms. B
Who is happier under the Prospect Theory?
A: $100 Tax return, $60 traffic ticket B: $40 in March Madness office pool
Loss Aversion Coefficient (Lambda)= 2 |
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Definition
Ms. B is presumably happier because the events are seen as separate. Mr. A sees the gain from event 1 ($100 tax return) and the loss from event 2 ($60 ticket) as separate events, where loss is twice as bad as an equivalent gain.
Mr A: v(100) + 2v(-60) = 100 - 20 = -20 (UNHAPPY, OVERALL LOSS)
Ms. B: v(40) = 40 (HAPPY, OVERALL GAIN)
However if Mr. A mentally combines the events, then... Mr.A: v(100-60) = v(40)=40 (EQUALLY AS HAPPY AS MS. B) |
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Term
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Definition
described the common human tendency to rely too heavily on the first piece of info offered ("anchor") when making decisions
Ex. Credit card --> class tended to provide answers based off of the minimum balance due rather than the second piece of info stating they couldn't afford to pay greater than or equal to the minimum payment due. |
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Definition
Collects measurement firm every member of the population. A complete enumeration of the almonds and population. No sampling error. Very costly - both money and time. |
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Definition
A subgroup of the elements of the population selected for participation in the study. Cost effective - both in terms of cost and money. But this Indians it also comes at a cost (error that comes from inferring about population from a sample.) |
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We have: small budget short time available large population size small variance in the characteristic low cost of sampling errors high cost of nonsampling errors destructive nature of measurement
Which should we use? A sample or a census? |
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We have: large budget long time available small population size large variance in the characteristic high cost of sampling errors low cost of nonsampling errors nondestructive nature of measurement
Which should we use? A sample or a census? |
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Definition
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Term
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Definition
1. Define the population 2. Determine the Sampling Frame 3. Select sampling technique 4. Determine the sample size 5. Execute the sampling process |
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Specific list of all the people in your target population and their contact information |
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What are the two main types of sampling techniques? |
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Definition
Nonprobability Sampling Techniques (Convenience, judgmental, quota, snowball), Probability Sampling Techniques (simple random sampling, systematic sampling, stratified sampling, cluster sampling |
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Definition
do not allow for objective evaluation of the precision of the sample results, i.e. how confident we are about generalizability |
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Definition
Attempts to obtain a sample of convenient elements; right place, right rime, (difficult to generalize inferences to a specific population) |
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Definition
form of convenience sampling; population elements are selected based on the judgment of the researcher; difficult to generalize inferences to a specific population |
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Definition
ensures that the composition of the sample is the same as the composition of the population with respect to the characteristic of interest
2-Stage sampling procedure:
1. Determinet attributes that are important (income, gender, residence) and determine their quota/upper limits (often quotas represent incidence in the population)
2. Sample elements selected based on convenience or judgment until the quote is met |
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Definition
an initial group of respondents is selected, usually at random through probability sampling; after being interviewed, these respondents are asked to identify others who belong to the target population of interest; subsequent respondents are selected based on the referrals; rare/low-usage products |
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Term
Simple Random Sampling (SRS) |
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Definition
each element in the population has a known and equal probability of selection. This implies that every element is selected independently of every other element. (all non-probability samples had "dependent" elements)
Often difficult to construct a sampling frame that will permit a simple random sample to be drawn |
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Term
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Definition
the sample is chosen by selecting a random starting point and then picking every ith element in succession from the sampling frame. The sampling interval, i, is determined by dividing the population size N by the sample size n and rounding to the nearest integer.
Ex. need a 20 person sample from a population of 100 people, i = 100/20 = 5, choose a random number between 1 and 5, lets pick 3. Select every 5th person in the list starting from 3, i.e. 3rd, 8th, 13th |
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Term
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Definition
Two stage sampling
Population is partitioned into non-overlapping groups, called strata and a sample is selected from each statum
1. Strata should be mutually exclusive and collectively exhaustive 2. The elements within a stratum should be as homogenous as possible, but the elements in different strata should be as heterogenous as possible
Elements are selected from each stratum by a random procedure, usually Simple Random Sample. |
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Term
Proportionate stratified sampling |
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Definition
size of the sample drawn from each stratum is proportional to the relative size of that stratum in the total population |
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Term
Disproportionate stratified sampling |
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Definition
size also depends on other factors |
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Term
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Definition
1. target population is first divided into mutually exclusive and collectively exhaustive subpopulations, or clusters.
Then a random sample of clusters is selected, based on a probability sampling technique such as SRS. For each selected cluster, either all the elements are included in the sample, or a sample of elements is drawn, preferably probabilistically |
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Term
Characteristics of sampling clusters |
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Definition
Elements within a cluster should be as heterogeneous as possible, but clusters themselves should be as homogeneous as possible.
Ideally each cluster should be a small-scale representation of the population. |
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Definition
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Definition
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Which type of sampling offers a quantifiable measure of sampling error? |
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Surveys can be used in both _______ and ___________ research. |
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Definition
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Term
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Definition
temporal displacement of an event whereby people perceive recent events as being more remote than they are and distant events as being more recent than they are; leads to over reporting of the frequency of events |
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Term
Prevent telescoping bias:
"How many gallons of soft drinks did you consume during the last four weeks?" |
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Definition
"How often do you consume soft drinks in a typical week? Please select from below:
1. ___ Less than once a week 2. ___ 1 to 3 times per week 3. ___ 4 to 6 times per week 4. ___ 7 or more times per week" |
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Definition
open-ended questions that respondents answer in their own words |
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Definition
specify the set of response alternatives and the response format; may be multiple-choice, dichotomous, or a scale |
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Definition
1. General, uninformative 2. New Information 3. Specific 4. Past behavior, demographics |
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Definition
refers to the testing of the questionnaire on a small sample of respondents to identify and eliminate potential problems
respondents should be drawn from the same population
best done via a personal interview, no matter the format of the actual survey; not always possible |
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Definition
Left: Bar chart Right: Histogram |
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Term
Relative Frequency Histogram |
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Definition
the height of each bar represents the proportion of the data (in percentages) in that bar; the height of the "bars" sums to 100% |
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Term
probability density histogram |
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Definition
the area of each bar represents the proportion of the data in that bar
total area inside the histogram is 1 |
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Term
Formula for mean of POPULATION distributions |
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Definition
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Term
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Definition
Standard Deviation of POPULATION Distributions |
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Term
Formula for mean of SAMPLE distributions |
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Definition
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Term
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Definition
often used when population SD is not available; "estimate" of population SD; the sample is likely to be less variable than population, therefore a correction is applied to "raise" the SD estimate for the population; the larger the value of sample size, N, the less effect will this correction have |
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Definition
Standard Deviation of SAMPLE distribution |
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Definition
a frequency distribution that is:
-Symmetrical -(+/-) SD from mean contains 68% of scores -All of the area under the curve = 100% |
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Definition
numbers expressed in standard deviation units
a.k.a. standard normal or unit normal |
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Definition
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Scores on the Math portion of the SAT are normally distributed with a mean of 514 (mu = 514) and a std dev of 117.
What is the z-score for George, who received a score of 527? |
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Definition
X= George's score mu = mean, 514 stddev = 117
(527-514)/117 = .11 |
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Term
We find that a student, George's z-score for his SAT math score of 527 is .11
If the mean is 514 and the std dev is 117, which percents of test takers did George do better than? |
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Definition
Z-score table states the probability of scoring equal to or greater than George is .4562.
So the percent of test takers George did better than is 1 - .4562 = .5438
So George did better than 54.38% of his peers! |
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Term
Distribution of sample means |
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Definition
imagine drawing multiple random samples from a population. For a particular survey question, you are able to collect data that we can measure the mean of, such as the average height of the participants.
If we keep repeating this process, finding more and more sample means, we can organize these sample means into their own distribution |
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Term
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Definition
EVERY distribution of sample means have the following characteristics:
1. mean will be equal to the population mean (mu) 2. standard deviation will always be equal to stddev/sqrt(N)
^^^^STANDARD ERROR OF THE MEAN = STANDARD DEVIATION OF THE SAMPLE MEAN DISTRIBUTION
The shape of the histogram will tend to be normal as N increases |
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Term
Standard Error of the Mean (SEM) |
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Definition
The typical distance between all possible sample means and the population mean
stdev / sqrt(N)
stdev = population stdev N = sample size |
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Term
Consider a small population of 4 values: 10 , 12, 14, and 16
A. Find population mean B. Find population standard deviation |
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Definition
A. 13 B. Standard Deviation = 2.24
10 - 13 = -3 12 - 13 = -1 14 - 13 = 1 16 -13 = 3
-3^2 = 9 -1^2 = 1 1^2 = 1 3^2 = 9
9 + 1 + 1 + 9 = 20 20/n = 20/4 = 5 sqrt(5) = 2.236
2.24 |
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Term
Why is Central Limit Theorem (CLT) important? |
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Definition
We can just do one single sample draw from the population. Do not need to repeat the sampling process multiple times, thus allowing for hypothesis testing. |
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Term
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Definition
"Is the sample mean different from the population mean?"
Simplest case is the one-sample test |
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FBI is investigating loan officers of a large US bank, for illegal mortgage practice. • The mean income of all bank loan officers is µ=$50,000. Also, the standard σ=$12,000 • FBI checks the paper of N=16 bank loan officers from this bank. The mean income of these 16 officers = $55,000 • Can we conclude that the bank indulged in illegal practice? |
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Definition
N = 16 Sample Mean = $55,000
Standard Error of the Mean (Standard Deviation of sample mean) = stdev/sqrt(N) = 12,000/sqrt(16) = $3,000
Find where $55,000 lands in a distribution where the mean is $50,000, and stdev (sterror) is $3,000
Find the probability that one will find an officer with a mean salary greater than $55,000 merely by chance.
z-score = (X-mu)/sterror = (55000 - 50000)/3000 - 1.67 ^^^ *** test statistic *** ^^ Probability in Z-Score table: 0.0475 = 4.75% chance of finding an officer who makes more than $55,000 a year "by chance"
In other words, the difference between the population mean and the sample mean merely due to chance is very unlikely
The bank is potentially guilty of fraudulent practice. |
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Definition
apriori = alpha
our level of significance (we decide it, but is typically 5% or 0.05) |
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Definition
set by the alpha value. If alpha is .05, the critical value is 1.65 because 1.65 in the z-table shows the probability closest to 0.05. |
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Definition
The value obtained from the "observed" mean of the sample "drawn" from the population.
Used to compute the test statistic (z-score, it is the X value) |
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Term
How can we calculate the standard deviation of the population when only given the sample size, and a portion of the population? |
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Definition
The Population Proportion sqrt(pi(1-pi)) where pi = portion
SD of the sample mean or standard error then is... sqrt((sqrt(pi(1-pi))/N) |
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Definition
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Definition
Standard Deviation of the sample mean
or
Standard Error |
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Term
How do we calculate the value of the sample proportion? |
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Definition
divide the number of observations by the sample size
ex. sample size = 30, 17 have red hair, p = 17/30 =0.567 |
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Definition
Z-Score of a value of a sample proportion |
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Term
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Definition
Represents probability that the null (status quo) is true and that this is not new information
ex. FBI investigation example, p = 4% so the probability that we AREN'T gaining new insights into the practices of the firm is very slim |
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Definition
Represents the level of significance; exhibits the probability of making a type 1 error (rejecting null, when null is true) |
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Term
What describes IF a treatment worked (or if the result is likely due to a sampling error?) |
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Definition
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Term
What describes HOW WELL a treatment worked? |
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Definition
Effect Size
"size of the effect" |
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Term
Imagine you're testing to see if a new "treatment" worked. The difference between the means (mean difference) should be.... |
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Definition
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Term
If Mbefore - Mafter NOT zero, what should we ask? |
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Definition
Is it due to chance or due to the treatment? |
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Term
When do we use a paired t test? |
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Definition
when the groups are related |
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Term
One-Tailed Hypotheses (Treatment example) |
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Definition
Null: the population's mean is NOT higher after treatment
Research (Alternative): The population's mean memory score is higher after treatment than before taking the drug |
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Term
In what table do we use degrees of freedom (df) in determining the area to the right of the critical value? |
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Definition
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How do we calculate the degrees of freedom? |
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Definition
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How do we find the t value? (Test Statistic) |
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Definition
t = (Mafter - Mbefore)/(stddev(sampling dist. of the difference)/sqrt(N))
N = sample size |
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Term
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Definition
Difference (D) is used for paired t-test |
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Term
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Definition
Provides a range of plausible values for a population parameter (e.g. population mean), about which we can be confident to a certain extent |
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Definition
UB = sample mean + (t critical)(SEM) |
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Term
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Definition
LB = sample mean - (t critical) (SEM) |
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Term
T Critical vs. T Test Statistic |
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Definition
T Critical comes from a table! T Test statistics are computed |
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Definition
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Term
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Definition
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The mean score on a test of scientific knowledge for a sample of 50 college graduates is M = 68.3 (SD = 12.4). Compute a 95% confidence interval around the mean.
What is the point estimate? |
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Definition
68.3
The sample mean (i.e. your best guess about the population mean) |
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Term
The mean score on a test of scientific knowledge for a sample of 50 college graduates is M = 68.3 (SD = 12.4). Compute a 95% confidence interval around the mean.
What are we looking for in terms of a range of values? |
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Definition
A range between LB and UB likely to contain the population mean 95%
Basically we are saying the population mean will be somewhere close to the sample mean. By finding the upper and lower bounds we are stating that sample mean is a good indicator of the population mean because from it we are able to derive a region in the distribution where the actual unknown population mean will fall 95% of the time. |
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Term
What do we use when we do not know the population SD? |
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Definition
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Term
What is the most plausible value of an unknown population mean? |
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Definition
Point estimate (i.e. the known sample mean) |
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Term
The further values are from the point estimate, the ___________ plausible they are. |
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Definition
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Term
What is the most plausible value of an unknown population mean? |
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Definition
Point estimate (i.e. the known sample mean) |
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Term
The further values are from the point estimate, the ___________ plausible they are. |
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Definition
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Term
Confidence Interval for a Mean Difference |
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Definition
difference between a sample mean and a population mean (as in, a single sample t test) |
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Term
What is the point estimate for a confidence interval for a mean difference? |
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Definition
The difference between the sample mean and the population mean (imagine a distribution with this difference at its center, where the x axis signifies the various differences between sample and population means). |
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Term
What does it mean when the 95% critical interval of the difference between the sample and population means contains 0? (as in a negative lower bound, positive upper bound) |
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Definition
It is quite likely that the difference between the sample mean and the population mean is 0. Thus, the observed mean was not significantly different. |
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Term
What do we use when we do not know the STANDARD DEVIATION of the POPULATION. |
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Definition
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Term
When samples sizes are large, the ____________ is a better approximation of the _____________. |
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Definition
When sample sizes are large, the sample SD is a better approximation of the population SD. |
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Term
Why is the critical value for a t distribution higher than z for smaller samples? |
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Definition
There is more "noise" in a t test-statistic (particularly for lower N), and therefore we want to have a higher threshold before we reject the NULL. |
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Term
If we have a two tailed test, what happens to the level of significance (alpha)? |
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Definition
It is divided equally into 2 equal parts
alpha = 0.05 a1 = 0.025 a2 = 0.025 |
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Definition
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Term
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Definition
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Term
What kind of test (one/two-tailed) would we use when we don't have any specific expectation, only a change? |
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Definition
Two-tailed hypothesis test |
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Term
When do we use chi-square tests? |
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Definition
When the data is nominal, and we are considering category membership; chi-square tests are used to analyze FREQUENCIES |
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Term
Two types of chi-square tests |
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Definition
Goodness of fit -> when there is 1 nominal variable
Independence ->when there are 2 nominal variables |
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Term
Goodness-of-fit Chi Square |
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Definition
used to compare observed sample distribution with an expected probability distribution; was the observed value significantly different from the expected value? |
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Term
degrees of freedom for chi square tests |
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Definition
df = number of categories - 1 |
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Term
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Definition
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Term
How do we get critical value when performing a chi square test? |
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Definition
finding degrees of freedom (df=number of categories -1) and the alpha (0.05) and check a chi square table. |
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Term
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Definition
Statistical examination of two or more variables which are described simultaneously |
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Term
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Definition
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Term
How do we find the degrees of freedom of a crosstab for a chi square test? |
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Definition
df = (number of categories - 1) * (number of categories - 1) |
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Term
How do we determine the expected frequencies (EF) if the NULL hypothesis is EXACTLY true? |
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Definition
EF = (Row Total*Column Total)/Total number of observations
***DO THIS FOR EACH CELL |
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Term
What do we ask when we perform an independent samples t |
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Definition
After treatments, if (measurement 1 - measurement 2 ) does NOT equal zero, is the difference likely due to chance or the treatment?
Does the treatment itself matter? |
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Term
Degrees of Freedom for an independent samples t test |
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Definition
df(1) + df(2) =
(N1 - 1) + (N2-1) |
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Term
which table do we consult for an independent samples t test's critical values? |
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Definition
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Term
t test statistic for independent samples t test |
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Definition
t = (M1 - M2)/stddev(the sampling distribution of the difference) |
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Term
What does ANOVA stand for? |
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Definition
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Term
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Definition
measures how far a set of numbers are spread out. A variance of zero indicates that all the values are identical. |
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Term
Why do we need One-Way F tests (ANOVA) if we already have independent sample t tests? |
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Definition
Because independent sample t tests are for two samples. Any greater amount of samples means we cannot use independent t tests anymore! |
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Term
ANOVA (Analysis of Variance) |
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Definition
A hypothesis testing procedure for evaluating mean differences between two or more treatments
**If used on only 2 groups, will bare same results as an independent samples t test |
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Term
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Definition
a function of sum of squared deviation from some mean value |
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Term
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Definition
Are the measurements very similar inside a particular group, and very different across groups? |
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Term
Sources of variability within treatments |
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Definition
individual differences, error |
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Term
Sources of variability across treatments |
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Definition
treatment effect, individual differences, error |
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Term
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Definition
used in ANOVA to compare the relative amount of variability created by treatment vs. individual differences and error
F = 1 if treatment has no effect; between and within group variability will be equal
F >1 If treatment has an effect, between group variability will be more than within group variability |
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Term
Degrees of freedom for ANOVA |
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Definition
df(between) = # groups - 1 df(within) = N - # groups |
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Definition
F= variability across treatments / variability within treatments |
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Definition
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