Assessment Primer

Why do Assessment?

Are you asking too little of your class?
 
Are your students approaching your course as hurdlers, barely clearing required levels of 
performance?  Or are they approaching your course like high jumpers, pushing themselves under 
your guidance to increasingly more challenging heights?  If your students aren't high jumpers, 
maybe it's because you aren't asking them to high jump.  By using appropriate assessment 
techniques, you can encourage your students to raise the height of the bar.

There is considerable evidence showing that assessment drives student learning.  More than 
anything else, our assessment tools tell students what we consider to be important.  They will learn 
what we guide them to learn through our assessments.

 
Traditional testing methods have been limited measures of student learning, and equally 
importantly, of limited value for guiding student learning.  These methods are often inconsistent 
with the increasing emphasis being placed on the ability of students to think analytically, to 
understand and communicate at both detailed and "big picture" levels, and to acquire life-long skills 
that permit continuous adaptation to workplaces that are in constant flux.  Moreover, because 
assessment is in many respects the glue that links the components of a course - its content, 
instructional methods, and skills development -  changes in the structure of a course require 
coordinated changes in assessment. 

This Primer is designed to welcome you to the world of classroom assessment.  The College Level 
One (CL-1) Team assumes you are here because you are interested in better ways to assess student 
learning in your class and in helping your students become more reflective and effective learners.  

One goal of this website is to provide resources that enable you to begin this journey to more 
effective assessment of student learning.  The first step is to articulate your course goals.  Once 
you have identified your course goals, this website presents Classroom Assessment Techniques or 
CATs that are aligned with them.  The CATs are a rich, eye-opening source of ideas and associated 
tools that have been extensively field-tested by your colleagues across the spectrum of SMET 
disciplines and post-secondary institutions.  We encourage you to explore the CATs to see how 
you can work with your class to assess their understanding, skills, and attitudes through concept 
maps, conceptests, Fermi tests, interviews, portfolios, and other related techniques and tools.  If 
you are not familiar with these forms of assessment, we are confident that you will discover, as we 
have, that they provide paths to a broader and deeper understanding of student learning for both 
you and your students.

We close by noting that assessment is undergoing exciting changes in college SMET courses.  The 
overarching intent of this website is to capture the vitality of assessment.  The CL-1 Team views 
assessment as a moving target and this website as a living product, providing both a mechanism 
for rapid dissemination of assessment-related developments and a forum for their discussion.  In 
this spirit, the CL-1 Team invites you to join the growing number of college SMET instructors 
who are identifying and developing new tools that can be used to assess student learning and to 
share your ideas and experiences with us.  We welcome your feedback and encourage you to 
contact us.


An Introduction to Assessment - the Basics


	What is assessment?

	Why do it?  

	Why do it in a particular way?  
 
This document addresses these important questions and provides an 
introduction to the basic concepts and terminology surrounding 
assessment.  The discussion builds toward a generalized model for 
course development.  Central to this discussion is the following key 
precept:  Assessment drives student learning.  


What Is Assessment?

Assessment is more than grades
To many, the word "assessment" simply means the process by which we assign students grades.  
Assessment is much more than this, however.  Assessment is a mechanism for providing 
instructors with data for improving their teaching methods and for guiding and motivating students 
to be actively involved in their own learning.  As such, assessment provides important feedback to 
both instructors and students. 

Assessment is Feedback for Both Instructors and Students 
Assessment gives us essential information about what our students are learning and about the 
extent to which we are meeting our teaching goals.  But the true power of assessment comes in 
also using it to give feedback to our students.  Improving the quality of learning in our courses 
involves not just determining to what extent students have mastered course content at the end of the 
course; improving the quality of learning also involves determining to what extent students are 
mastering content throughout the course.

Thus, in addition to providing us with valuable information about our students' learning, 
assessment should assist our students in diagnosing their own learning.  That is, assessment 
should help students "become more effective, self-assessing, self-directed learners."1  Various 
classroom assessment techniques (CATs) have been developed with this in mind.  The CATs 
provided in the FLAG site have been field-tested and shown to be effective at both measuring 
student mastery of content and at providing students with the feedback they need to become active 
participants in the learning process.  Indeed, such feedback can positively influence what our 
students learn because assessment drives student learning.

Assessment Drives Student Learning
The types of assessment usually performed in first-year science, math, engineering, and 
technology (SMET) courses--giving students tests--merely inform students about their grade, or 
ranking, after they have received instruction.  In addition, these common testing techniques--which 
typically test for fact-based knowledge and algorithmic problem solving--tell our students that this 
is the type of knowledge we think is most important.  That is, we appear to value the 
understanding of concepts at a relatively low level.

Given that this is the type of assessment our students most frequently encounter, and that it will 
eventually lead to their final course grades, students learn to study the content in our courses in an 
expeditious way that allows them to succeed in passing many first-year SMET courses without 
necessarily developing deep understanding of concepts.  It is our assessment that drives students 
learning.

In fact, assessment drives student learning whether we want it to or not.  The consequences of 
relying upon our "tried and true" assessment methods are profound; these assessment methods 
may actively promote superficial learning.  If we wish to actively steer what our students learn, and 
how well they learn it, we must (1) actually decide what we want our students to take away from 
the course, and (2) choose our classroom assessment techniques appropriately (Anderson & 
Sosniak, 1994; National Research Council, 1996; Tobias & Raphael, 1997; Wiggins, 1998).  The 
importance of setting course goals--articulating them and writing them down--cannot be overstated.  
Evaluating the extent to which we have attained our stated course goals is the primary motivation 
for why we "do assessment".  Furthermore, ensuring that our assessment techniques can measure 
our stated goals is the reason for why we "do assessment in a particular way". 


Why do assessment?

To evaluate attainment of course goals 
For every course we teach, we make decisions about what we want our students to know and be 
able to do by the end of the semester.  Though we might not always formalize these goals by 
writing them down, we still make decisions about the curriculum, the instructional methods, and 
the assessment techniques we will employ.  In terms of curriculum, we decide which topics to 
cover, and how they connect with previous and forthcoming topics.  We also decide which 
instructional methods we will use to deliver the curriculum, be they lectures, group activities, 
readings, homework assignments, etc.  Similarly, we decide what assessment techniques we will 
use (e.g., multiple-choice tests).  Thus, the decisions we make reflect our goals for the course 
whether we state them or not.  It is important, therefore, to formalize course goals while the course 
is still in its planning stage.  The FLAG site includes a section on Aligning Goals CATs to assist 
with identifying course goals.

Formalizing our goals is only the first step, however.  We must also measure the extent to which 
we are attaining these goals.  This is why we do assessment.  Logically, we must choose 
classroom assessment techniques that are appropriately suited to measuring our particular goals.  
That is, we must align our assessment techniques with our stated goals. 


Why do assessment in a particular way?

To align assessment with stated goals 
The most commonly employed CAT in first-year SMET courses is the multiple-choice test.  Such 
tests are usually most effective at measuring fact-based knowledge and ability to perform 
algorithmic problem-solving.  If our stated goals are that students be able to recite facts and to 
solve simple algorithmic problems, then in fact the chosen assessment technique is well aligned 
with the stated goals.  However, if our goals include different student outcomes than these (e.g., 
an understanding of the scientific "process", a lifelong interest in the subject, the ability to critically 
analyze science in popular media, etc.), then this assessment technique will not provide useful 
feedback about attainment of these goals.  

Furthermore, misaligned assessment techniques convey to our students the wrong message about 
what we want them to take from the course.  As suggested previously, our choice of assessment 
technique drives student learning.2

These are the basics of assessment--the fundamental principles behind why we do it and why we 
do it in a particular way.  At this point, if you are ready to stop reading about assessment and are 
ready to start implementing some of what you've just learned, the FLAG site provides a facility for 
formalizing course goals and a suite of field-tested classroom assessment techniques that are well 
suited for a variety of course goals. 

But you may also wish to go beyond the basics of assessment.  Concerns about assessment are not 
the only ones faced in the development and refinement of SMET courses; decisions about 
curriculum and instructional methods are equally important, and assessment plays a vital role in 
guiding these decisions.  A more in-depth discussion of how curriculum, instructional methods, 
and assessment fit together is provided in "Assessment Within the Broader Context of Course 
Development," where we describe a generalized model for course development that builds upon the 
precepts that assessment drives student learning and that assessment provides feedback for both 
instructors and students.  You will then find the FLAG site's facility for formalizing course goals 
and its suite of field-tested classroom assessment techniques to be of even greater value.  



Assessment within the Broader Context of Course Development: A 
More In-Depth Look at Assessment - The Holistic View

Assessment Drives Course Development

Assessment plays a dual role: It drives student learning and it provides important feedback for both 
students and instructors.  In An Introduction to Assessment: The Basics, we focused primarily on 
the former of these two roles.  Students want to "do well" (receive high grades) in their courses, 
and they use our assessment techniques as the means for determining what it is we expect them to 
learn and for diagnosing how well they are learning it.  Students will adapt their mastery of course 
content to what our assessment techniques require of them.  Thus, if we want students to achieve 
our course goals, we must choose appropriate assessment techniques that guide our students to 
those goals. 

In this document, we build upon the feedback role of assessment.  In particular, we discuss the 
feedback that assessment provides the instructor, and the ways in which assessment drives course 
development.  We want our students to "do well" (attain our course goals), and we use our 
assessment techniques as the means for diagnosing how well our students are doing.  We can 
modify our curriculum and instructional methods based on what our assessment techniques tell us 
about what students are learning compared to what we want them to learn.  We must, therefore, 
choose assessment techniques that will give us useful feedback for refining our curriculum and our 
instructional methods so that we achieve our course goals. 

What follows is a generalized model for course development, within which assessment plays a 
critical role.  Not surprisingly, this course development model centers on course goals.  As we will 
see, our goals determine the curriculum, instruction, and assessments that are best suited for the 
course, and we will see that assessment serves as the "feedback loop" wherein we evaluate the 
extent to which our curriculum and instruction choices are leading to the attainment of course goals 
so that we may then modify the curriculum and instructional methods based on this evaluation. 


A Generalized Model for Course Development

 
Figure 1

Curriculum, Instruction, and Assessment
The three primary components of any course are the curriculum (the "content"), the instructional 
methods used to deliver the curriculum, and the assessment techniques with which our success in 
attaining course goals is evaluated.  These three components (curriculum, instruction, assessment-
CIA) are inextricably linked, and are bound together by the goals we set for the course.  The CIA 
model presented here requires that goals be formalized at the outset, which is to say that goals be 
clearly articulated.  Ultimately, it is our course goals that set the standard against which the success 
of the course development effort must be measured.  In this context, the role of assessment is to 
measure the efficacy of our curriculum and of our instructional methods with respect to stated 
course goals.  This is how curriculum, instruction, and assessment are linked in the CIA model. 

While formalizing goals is the most important part of course development, it is only the first step.  
The path through the course development process can be envisioned as a "road map", with goals at 
the beginning, pointing the way, to assessment at the end, telling us if we have reached our 
destination or if we need to retrace our steps.  This course development "road map" (Figure 1) 
provides a detailed set of directions, with specific actions to be taken at several signposts along the 
way.  Starting from formalizing course goals, the "directions" are as follows:

· translate goals into Measurable Student Outcomes
· determine Levels of Expertise required to achieve outcomes
· select both Curriculum and Classroom Assessment Techniques
· choose and implement Instructional Methods
· conduct Assessment and evaluate--were Measurable Student Outcomes realized? 

Let's consider these steps in turn.

Translating Course Goals Into Measurable Student Outcomes
Assessment can measure the extent to which course goals have been achieved, but only if those 
goals are measurable.  For the most part, however, course goals are too broad or too abstract to 
measure directly.  This is one of the first difficulties often encountered in the course development 
process.  For example, one course goal in an introductory astronomy course might be that 
"students understand the seasons."  But how does one measure "understand"? This goal can be 
made more measurable by identifying specific outcomes one would expect from a student who 
"understands" the seasons.  For example: The student can "define seasons" and can "distinguish 
the importance of different factors such as tilt and distance." 

Thus, once goals have been formalized, the next step in course development is to translate the often 
abstract language of course goals into a set of concrete measurable student outcomes.  Measurable 
student outcomes are specific, demonstrable characteristics--knowledge, skills, values, attitudes, 
interests--that will allow us to evaluate the extent to which course goals have been met.  For each 
course goal, identify the principal outcomes one would expect from a student who has achieved 
that goal, keeping in mind that our ability to measure the achievement of course goals will be 
determined entirely on the basis of these measurable student outcomes.  Of course, knowing what 
kinds of outcomes are actually measurable requires knowledge of the kinds of assessment 
techniques that are available, and what each technique can and cannot measure.  Don't worry: we'll 
discuss different assessment techniques later, and the section on Classroom Assessment 
Techniques presents a variety of these assessment methods and how they connect with different 
measurable student outcomes.  Figure 2 gives an example of translating a specific course goal (in 
the context of dental health) into measurable student outcomes. 

 
Figure 2 - An example of translating a course goal into measurable student 
outcomes.

Determining Levels of Expertise Required to Achieve Measurable Student Outcomes
Having translated course goals into measurable student outcomes, we are one step closer to 
selecting the curriculum, instructional methods, and assessment techniques that will constitute the 
course.  In order to select the CIA that are best suited for the course goals we have identified, it is 
necessary to determine the levels of expertise that are required for achieving the measurable student 
outcomes that go with each course goal.  The levels of expertise that we assign to measurable 
student outcomes are important because they are the factors that most directly determine the 
appropriate choices of CIA for the course. 

What do we mean by "levels of expertise"? The various student outcomes that we assign to each 
course goal require different levels of mastery of course content.  Some student outcomes require 
no more than students simply knowing the correct answer.  However, many student outcomes 
require more sophisticated levels of understanding--or levels of expertise.  Consider again the 
dental hygiene example above (Figure 2): The measurable student outcome of "knows the active 
ingredient in toothpaste" requires only that students memorize the correct answer (fluoride), while 
the outcome of "can describe how poor dental hygiene can lead to poor overall health" requires a 
much more sophisticated level of understanding, involving synthesis of multiple facts and 
concepts.  Again, measurable student outcomes vary in the levels of expertise required to achieve 
them.  Accordingly, the criteria by which we measure student success in achieving desired 
measurable student outcomes--our classroom assessment techniques--should be capable of 
assessing a variety of levels of expertise.  In general, this means using a variety of classroom 
assessment techniques.  Let's consider how to go about determining levels of expertise for our 
measurable student outcomes.  


Bloom's Taxonomy of Educational Objectives

One of the most widely used ways of organizing levels of expertise is according to Bloom's 
Taxonomy of Educational Objectives.3  Bloom's Taxonomy (Tables 1-3) uses a multi-tiered scale 
to express the level of expertise required to achieve each measurable student outcome.  Organizing 
measurable student outcomes in this way will allow us to select appropriate classroom assessment 
techniques for the course.

There are three taxonomies.  Which of the three to use for a given measurable student outcome 
depends upon the original goal to which the measurable student outcome is connected.  There are 
knowledge-based goals, skills-based goals, and affective goals (affective: values, attitudes, and 
interests); accordingly, there is a taxonomy for each.  Within each taxonomy, levels of expertise 
are listed in order of increasing complexity.  Measurable student outcomes that require the higher 
levels of expertise will require more sophisticated classroom assessment techniques.  

The course goal in Figure 2--"student understands proper dental hygiene"--is an example of a 
knowledge-based goal.  It is knowledge-based because it requires that the student learn certain 
facts and concepts.  An example of a skills-based goal for this course might be "student flosses 
teeth properly."  This is a skills-based goal because it requires that the student learn how to do 
something.  Finally, an affective goal for this course might be "student cares about proper oral 
hygiene." This is an affective goal because it requires that the student's values, attitudes, or 
interests be affected by the course. 

Table 1:  Bloom's Taxonomy of Educational Objectives for Knowledge-Based Goals
Level of Expertise
Description of Level
Example of Measurable 
Student Outcome

1. Knowledge
 Recall, or recognition of terms, 
ideas, procedure, theories, etc. 
 When is the first day of 
Spring?

2. Comprehension
 Translate, interpret, extrapolate, 
but not see full implications or 
transfer to other situations, closer 
to literal translation.
 What does the summer 
solstice represent?

3. Application
 Apply abstractions, general 
principles, or methods to specific 
concrete situations.
 What would Earth's seasons 
be like if its orbit was 
perfectly circular?

4. Analysis
 Separation of a complex idea into 
its constituent parts and an 
understanding of organization and 
relationship between the parts.  
Includes realizing the distinction 
between hypothesis and fact as 
well as between relevant and 
extraneous variables.
 Why are seasons reversed in 
the southern hemisphere?

5. Synthesis
 Creative, mental construction of 
ideas and concepts from multiple 
sources to form complex ideas into 
a new, integrated, and meaningful 
pattern subject to given 
constraints.
 If the longest day of the year 
is in June, why is the 
northern hemisphere hottest 
in August?

6. Evaluation
To make a judgment of ideas or 
methods using external evidence 
or self-selected criteria 
substantiated by observations or 
informed rationalizations.
What would be the important 
variables for predicting 
seasons on a newly 
discovered planet?



Table 2: Bloom's Taxonomy of Educational Objectives for Skills-Based Goals
Level of Expertise
Description of Level
Example of Measurable 
Student Outcome

Perception
Uses sensory cues to guide actions
Some of the colored samples 
you see will need dilution 
before you take their spectra.  
Using only observation, 
how will you decide which 
solutions might need to be 
diluted?

Set
Demonstrates a readiness to take 
action to perform the task or 
objective
Describe how you would go 
about taking the absorbance 
spectra of a sample of 
pigments?

Guided Response
Knows steps required to complete 
the task or objective
Determine the density of a 
group of sample metals with 
regular and irregular shapes.  

Mechanism
Performs task or objective in a 
somewhat confident, proficient, 
and habitual manner
Using the procedure 
described below, determine 
the quantity of copper in 
your unknown ore.  Report 
its mean value and standard 
deviation.

Complex Overt 
Response
Performs task or objective in a 
confident, proficient, and habitual 
manner
Use titration to determine the 
Ka for an unknown weak 
acid.

Adaptation
Performs task or objective as 
above, but can also modify actions 
to account for new or problematic 
situations
You are performing titrations 
on a series of unknown acids 
and find a variety of 
problems with the resulting 
curves, e.g., only 3.0 ml of 
base is required for one acid 
while 75.0 ml is required in 
another.  What can you do to 
get valid data for all the 
unknown acids?

Organization
Creates new tasks or objectives 
incorporating learned ones
Recall your plating and 
etching experiences with an 
aluminum substrate.  Choose 
a different metal substrate 
and design a process to 
plate, mask, and etch so that 
a pattern of 4 different metals 
is created.



Table 3: Bloom's Taxonomy of Educational Objectives for Affective Goals
Level of Expertise
Description of Level
Example of Measurable 
Student Outcome

Receiving
Demonstrates a willingness to 
participate in the activity
When I'm in class I am 
attentive to the instructor, 
take notes, etc.  I do not read 
the newspaper instead.

Responding
Shows interest in the objects, 
phenomena, or activity by seeking 
it out or pursuing it for pleasure
I complete my homework 
and participate in class 
discussions.

Valuing
Internalizes an appreciation for 
(values) the objectives, 
phenomena, or activity
I seek out information in 
popular media related to my 
class.

Organization
Begins to compare different 
values, and resolves conflicts 
between them to form an internally 
consistent system of values
Some of the ideas I've 
learned in my class differ 
from my previous beliefs.  
How do I resolve this?

Characterization 
by a Value or 
Value Complex
Adopts a long-term value system 
that is "pervasive, consistent, and 
predictable"
I've decided to take my 
family on a vacation to visit 
some of the places I learned 
about in my class.



To determine the level of expertise required for each measurable student outcome, first decide 
which of these three broad categories (knowledge-based, skills-based, affective) the corresponding 
course goal belongs to.  Then, using the appropriate Bloom's Taxonomy, look over the 
descriptions of the various levels of expertise.  Determine which description most closely matches 
that measurable student outcome.  As can be seen from the examples given in the three Tables, 
there are different ways of representing measurable student outcomes, e.g., as statements about 
students (Figure 2), as questions to be asked of students (Tables 1 and 2), or as statements from 
the student's perspective (Table 3).  You may find additional ways of representing measurable 
student outcomes; those listed in Figure 2 and in Tables 1-3 are just examples.  

Bloom's Taxonomy is a convenient way to describe the degree to which we want our students to 
understand and use concepts, to demonstrate particular skills, and to have their values, attitudes, 
and interests affected.  It is critical that we determine the levels of student expertise that we are 
expecting our students to achieve because this will determine which classroom assessment 
techniques are most appropriate for the course.  Though the most common form of classroom 
assessment used in introductory college courses--multiple choice tests--might be quite adequate for 
assessing knowledge and comprehension (levels 1 and 2, Table 1), this type of assessment often 
falls short when we want to assess our students knowledge at the higher levels of synthesis and 
evaluation (levels 5 and 6).4

Multiple-choice tests also rarely provide information about achievement of skills-based goals.  
Similarly, traditional course evaluations, a technique commonly used for affective assessment, do 
not generally provide useful information about changes in student values, attitudes, and interests.

Thus, commonly used assessment techniques, while perhaps providing a means for assigning 
grades, often do not provide us (nor our students) with useful feedback for determining whether 
students are attaining our course goals.  Usually, this is due to a combination of not having 
formalized goals to begin with, not having translated those goals into outcomes that are 
measurable, and not using assessment techniques capable of measuring expected student outcomes 
given the levels of expertise required to achieve them.  Using the CIA model of course 
development, we can ensure that our curriculum, instructional methods, and classroom assessment 
techniques are properly aligned with course goals.  

Note that Bloom's Taxonomy need not be applied exclusively after course goals have been 
defined.  Indeed, Bloom's Taxonomy and the words associated with its different categories can 
help in the goals-defining process itself.  Thus, Bloom's Taxonomy can be used in an iterative 
fashion to first state and then refine course goals.  Bloom's Taxonomy can finally be used to 
identify which classroom assessment techniques are most appropriate for measuring these goals. 

Selecting Course Curriculum (Content) and Classroom Assessment Techniques
We are now at the point in the course development "road map" where concrete decisions must be 
made about what will be included in the course curriculum.  As the instructor of the course, 
choices about course content are entirely yours to make based upon what you want your students 
to take from the course.  It would be beyond the scope of this document to attempt to discuss 
specific choices about curriculum in detail.  We do comment, however, that here again goals are 
paramount.  If you are working from an existing syllabus (either your own or someone else's), 
take this opportunity to critically re-examine each component of the curriculum with respect to your 
course goals.  Are there topics in the syllabus that are not related to one or more course goals? 
Don't include content merely because "it's always been done that way" or because "it's important".  
If a topic is important, it will be reflected in your goals.  If an "important" topic is not reflected in 
your course goals, you may wish to re-visit the goals themselves.  In any case, each and every 
aspect of the curriculum should connect clearly to course goals.  

This is also the point in the course development "road map" where specific classroom assessment 
techniques (CATs) must be selected based upon measurable student outcomes and their associated 
levels of expertise.  The FLAG site was designed primarily to help you through this step in the 
course development process.  Provided for your use are a variety of CATs that have been tested in 
the field and which are authored by national experts in the use of that particular technique.  To be 
sure, the CATs provided in the FLAG site are but a subset of innovative CATs available from a 
variety of resources.  The CATs provided in the FLAG site should give you a good start. 

The CATs selected in this step will provide the feedback you need to evaluate the extent to which 
yours course goals have been achieved.  Thus, it is imperative that the CATs you select be properly 
matched with your measurable student outcomes.  The FLAG site provides a facility for helping 
you do this. 

Choosing and Implementing Instructional Methods
With your course goals formalized, having translated those goals into measurable student outcomes 
and assigning to each appropriate levels of expertise, and having selected the course curriculum 
and CATs, we are finally in a position to actually teach.  That is, we are at the point in the course 
development "road map" where we choose and implement the instructional methods that will best 
guide our students to attainment of our course goals. 

As with choosing curriculum and assessment, the choice of instructional methods must be guided 
by our course goals and, perhaps even more so, by the levels of expertise associated with 
measurable student outcomes.  For example, suppose that two of the course goals in an 
introductory engineering course are that (1) students learn how to "design simple machines that 
satisfy realistic constraints" and (2) that students "can work effectively as part of a design team".  
A common measurable student outcome for these goals might be that "students, working in a team, 
can design a device, using simple raw materials, that protects an egg when dropped from a height 
of two stories".  This measurable student outcome is at the "Organization" level of expertise 
(Bloom's Taxonomy of Educational Objectives for Skills-Based Goals; Table 2) because it requires 
students to "create new tasks or objectives incorporating learned ones".  Traditional lecturing alone 
would not be a sufficient instructional method in this case.  Instead, an instructional method that 
emulates teamwork and that promotes creative thought would be more appropriate.  That is, a more 
collaborative instructional method is called for.  

A variety of instructional methods have been developed for guiding students to the different levels 
of expertise represented by the goals of our course.  One commonly used instructional method--
collaborative learning--is described in detail in the College Level One's Collaborative Learning 
website (http://www.wcer.wisc.edu/archive/cl1/cl).  In fact, you will find that collaborative learning 
instructional methods are appropriate and useful for a wide variety of goals, outcomes, and levels 
of expertise. 

Conducting Assessment and Evaluating Attainment of Goals: Closing the Feedback Loop
It is in this final step of the course development process that we harness the power of the data 
provided by the CATs used during the implementation of the course.  Some of this assessment data 
may be used for assigning grades to our students.  Ultimately, however, the real value of this 
assessment data comes when we use it for improving the course.  That is, our assessment data 
provide us with critical feedback for evaluating what we've done: What works and what doesn't? 
Depending upon the CATs we have chosen, this feedback may be used either at the end of the 
course (to summarize the efficacy of our course development efforts) or along the way (to inform 
our course development efforts in progress).  When assessment data is used to evaluate the course 
in summary fashion at the end, it is called summative.  When assessment data is used to modify the 
course while it is in progress, it is called formative.  Either way, the point of assessment is to give 
us the information we need for evaluating achievement of our course goals.

How, specifically, do we perform this evaluation? By what criteria do we know if we have 
achieved our goals? Our measurable student outcomes are the key: If these outcomes are realized, 
we will know that we have attained our course goals.  Look at the assessment data.  Did your 
students achieve the hoped-for outcomes, and at the desired levels of expertise? Using the 
engineering example from above, perhaps the egg survived but only because one student in the 
team did all of the work, i.e., the outcome related to teamwork was not realized.  How might you 
modify the course to better foster effective teamwork? Perhaps students needed more guidance on 
how to work collaboratively; consider how the curriculum and/or instructional methods might be 
changed to accomplish this.  Or perhaps it is the teamwork goal itself that needs refining.  It is this 
important, evaluative step that allows you to determine the extent to which you are reaching your 
course goals and to decide if there are changes you would like to make.

We close this section by noting that the terms assessment and evaluation are often incorrectly used 
interchangeably.  Assessment is the collecting of data to inform both the instructor and the student 
as to how the course is progressing (formative) or how it has ended (summative).  Assessment 
involves gathering data via one or more classroom assessment techniques.  Evaluation is what we 
do with these data once we have them.  Once we have acquired the assessment data, it is up to us 
to judge the efficacy of our instructional methods, the content of our course, and the achievement 
of our course goals.  

 
Figure 3 - Road Map of Course Development.


Summary

Assessment Is Feedback for both Students and Instructors
The perspective that has been advocated here is that we can use carefully constructed classroom 
assessment techniques as a means of determining whether or not we are meeting our stated course 
goals, not just for assigning our students grades.  For us, classroom assessment can help us 
answer the following questions:
· To what extent are my students achieving the stated course goals?
· How should I allocate class time for the current topic?
· Can I introduce this topic in a more effective way?
· What parts of this course are my students finding most valuable?
· How will I change this course the next time I teach it?
· Which grades do I assign my students?

For our students, classroom assessment answers a different set of questions:
· Do I know what my instructor thinks is most important?
· Am I mastering the course content?
· How can I improve the way I study in this course?
· What grade am I earning in this course?

Answering these questions and others can inform and improve the quality of student learning in 
our classes.


A Charge to Change

We can not emphasize enough how important it is to actually write down your course goals and 
share them with your students.  Our goals are what bind the course together (Figure 3).  Our 
choices of curriculum, instruction, and assessment are all guided by--and held together by--our 
goals.  Once your course goals are set, questions about instruction, assessment, and grading will 
be much more focused.  This is a small step beyond the assessment strategies that most faculty are 
already doing; yet with a small investment in planning, the data acquired can provide valuable 
feedback for improving the quality of student learning.  And ultimately, our students are what 
course development is all about. 


Resources
· Aligning Goals to CATs
· Classroom Assessment Techniques (CATs)


References
Angelo, T. A. & Cross, K. P. (1993). Classroom assessment techniques: A handbook for 
college teachers. San Francisco: Jossey-Bass.

Bloom, B. S., et al. (1994). Excerpts from the ÒTaxonomy of educational objectives, the 
classification of educational goals, handbook I:  Cognitive domain.Ó In L. W. Anderson & L. A. 
Sosniak (Eds.), BloomÕs taxonomy: A forty-year retrospective. Chicago: University of Chicago 
Press.

Brissenden, G., Duncan, D. K., &. Slater, T. F. (in preparation). A survey of primary 
course goals of astronomy faculty.

Gronlund, N. E. (1991). How to write and use instructional objectives, Fourth Ed. New 
York: Macmillan Publishing Co.

Krathwohl, D. R., Bloom, B. S., & Masia, B. B. (1956). Taxonomy of educational 
objectives, the classification of educational goals, handbook II: Affective domain. New York: 
David McKay Co., Inc.

Linn, R. L. (1995). Measurement and assessment in teaching (7th ed.). Englewood Cliffs, 
NJ: Merrill.

National Research Council (1996). National science education standards. Washington, DC: 
National Academy Press.

Tobias, S & Raphael, J. (1997). The hidden curriculumÑfaculty-made tests in science, 
Part I: Lower-division courses. New York: Plenum Press.

Wiggins, G. P. (1998). Educative assessment: Designing assessments to inform and 
improve student performance. San Francisco: Jossey-Bass.


The Authors

Gina Brissenden
University of Chicago
American Astronomical Society Education Office

 
Gina Brissenden is the national education specialist for the American Astronomical Society.  She 
studies issues related to teaching introductory astronomy at the university level, including 
alternative conceptions in astronomy, gender equity in the science class, and progressive 
assessment. In 1998 she received the Dr. Brenda Pfaehler Award of Excellence in Fostering 
Student Learning.









Tim Slater
Physics Department
Montana State University-Bozeman

 
Tim  is Project Science Director for the NASA Center for Educational Resources CERES Project 
and a research assistant professor in the Department of Physics at Montana State University-
Bozeman.  Tim is working on developing Internet-based hands-on activities that take the form of 
Information Rich Problem Solving Activities Integrating Technology.  Tim is also working on the 
CERES Astronomy site, the Yohkoh Solar X-Ray Public Outreach Project (YPOP Solar Physics), 
and an On-Line REAL-TIME Science DATA System.  Tim earned his BS in Physical Science and 
Ed in Science Education at Kansas State University in 1989, his MS in Physics & Astronomy at 
Clemson University in 1991, and Ph.D. in Geological Sciences from University of South Carolina 
in 1993 with a focus on astronomy education.  Tim is also currently serving on the American 
Association of Physics Teachers Astronomy Education Committee.


Footnotes
1. Angelo & Cross, 1993, p. 4

2. Anderson & Sosniak, 1994; National Research Council, 1996; Tobias & Raphael, 1997; 
Wiggins, 1998

3. Bloom et al., 1994; Gronlund, 1991; Krathwohl et al., 1956

4. Bloom et al., 1994; Tobias & Raphael, 1997