Cost
Analysis of Online Courses
John Milam
University of Virginia
Introduction
As institutions witness the
phenomenal growth of virtual universities, cybercolleges, distance learning
programs, and web-based courses, how prepared are they for making the decisions
about resources which confront them?
How much does it cost to
develop an online course and what is the “break-even” point in enrollment? Is a distance learning program
cost-effective and how should this be measured? How much effort and funding should be put into course
development? Even if a program loses
money, how much is it worth for the institution to be seen as a leader in the
use of technology? Does it take less
faculty time to run an online course?
What are the computing support needs for these courses and does it make
sense to pool resources across departments or schools? What is the best use of scarce resources to
move into this arena? Is it cheaper and
more efficient to use a vendor such as University On-Line or e-college.com to
develop the courses?
These are some of the many
questions which may be addressed if institutions build a resource allocation
model and planning process for developing online courses. An entirely different, but related, set of
questions needs to be addressed in terms of assessment. While there are many worthy topics for this
type of inquiry, the specific focus of this paper is on cost analysis of online
courses.
Of course, the topic of
online courses is not the only pressing question which suggests the need for a
cohesive planning process and better resource allocation models. It is, though, perhaps the most costly to
ignore; not only in terms of cost-effectiveness in using resources, but more
importantly in taking advantage of the small window of opportunity which is now
available for institutions to develop an online presence. There is fierce and aggressive competition
from all sectors in the online market for higher education. Without the types of cost analysis described
in this paper, colleges and universities are ill-prepared to meet this
challenge and may find themselves left out of the race to capture the huge but
finite market of online enrollment.
Literature Review
Unfortunately, while there
is a growing literature on how to build web-based courses, develop online degree
programs, and incorporate best practices in instructional design, there is much
less written about assessment and the success of these courses in meeting
student and academic needs. Even less
is written about the resource allocation issues which are involved, such as
faculty workload, comparing costs between traditional and online courses, and
computing support.
A new resource is now
available for planners in the Flashlight Cost Analysis Handbook (Ehrmann
and Milam, 1999), published by the
Teaching, Learning, and Technology (TLT) Group, an affiliate of the American
Association for Higher Education. This
is the most recent in a series of online and print tools in the Flashlight
Program, started in 1993 as part of the Annenberg/CPB Projects to “help
educational programs understand and shape the consequences of their own uses of
computing, video, and telecommunications.”
The Flashlight Program
includes: (1) the Current Student Inventory (CSI), a 500 question/item bank and
tool kit for survey development about the use of technology in teaching; (2)
the new and evolving Faculty Inventory, of which Part I helps users compare
faculty and student perceptions about the use of instructional technology; (3)
Flashlight Online, a web-based tool for managing the CSI; (4) the Flashlight
“Tool Series,” involving subscription-based access to new tools and updates;
(5) the Flashlight Network, for working with institutions and organizations in
a wide range of activities such as Roundtables; (6) a monthly email newsletter,
F-LIGHT; and (7) the Cost Analysis Handbook with its economic model.
In addition to a detailed
discussion with examples of how to build cost analysis models, the Handbook
provides advise about many of the organizational constraints which emerge when
attempting this kind of resource allocation process, such as team development
in model building, shared perceptions of project outcomes, and focusing on the
unique cost drivers in a particular institutional setting. Aimed at all types of uses of technology in
teaching, the Handbook is not focused primarily to online courses, but is
easily adapted for this purpose.
This type of inquiry is also
well served by an understanding of the more general costing literature in
higher education. The NCHEMS cost of
instruction model has been in place for almost thirty years, and is perhaps
most useful today, when institutional research offices have the tools to build
online data marts and data warehouses which merge financial and student datasets. The heart of the NCHEMS model involves the
use of course enrollment data in an induced course load matrix (ICLM), first
championed by Suslow (1976). The ICLM,
with its focus on departmental consumption and contribution ratios of student
credit hours (SCH), is equally valuable in modeling the enrollment of traditional
and online courses. The NCHEMS model
is still used by some state higher education executive offices (SHEEOs) to
calculate discipline-specific staffing ratios, based on student credit hour
productivity.
Similarly, the rich
literature of the National Association for College and University Business Officers
(NACUBO) for indirect cost recovery and micro- and macro-costing is invaluable
to this effort. This includes Cost Accounting in Higher Education:
Simplified Macro- and Micro-Costing Techniques (Jenny, 1996); A Cost Accounting Handbook for Colleges and
Universities (Hyatt, 1983); and the NACUBO Handbook: College and University
Budgeting (Meisinger and Dubeck, 1984). Another useful monograph, prepared by a consortium of
institutions and organizations in Great Britain, is Management Information for Decision-Making: Costing Guidelines for
Higher Education Institutions (Joint Funding Councils, 1997).
While models may be built
without attention to these standards in cost analysis, they will fail to
address some of the complexities of enrollment, space utilization, departmental
and institutional overhead, and faculty workload. This is not to say that only complex models should be built, but
that any model development needs to be done with a clear set of assumptions. If assumptions about revenue, for example,
will be ignored because student tuition estimates and financial aid data are
not available or are too complex to be analyzed within the timeframe and
staffing level, this needs to be recognized as a limitation of the model.
Most important to take from
the cost literature are the concepts of: (1) the ICLM for enrollment and departmental
consumption/contribution; (2) space utilization and allocation costs; (3)
revenue stream based on tuition and fees minus financial aid and tuition
discounting; (4) faculty workload; and (5) administrative overhead at the
department, college/school, and institution-wide levels. The reader is referred to Jenny (1996) for a
more complex treatment of these concepts.
Jenny provides specific examples for costing at the course level.
Methodology
The Flashlight cost analysis
approach is being implemented in different ways at different institutions. The Handbook includes four case studies,
each of which involves a unique
resource allocation question and an individualized version of the
model. However, the purpose and basic
steps are the same.
The focus of the methodology
is on activity based-costing (ABC). ABC is a way of looking at costs that cross
the traditional building blocks of institutions, for which a specific account
or set of accounts are inadequate to track expenditures and revenues. As used at institutions such as Indiana
University and its campuses such as Indiana University-Purdue University
Indianapolis, ABC is part of a larger approach called Responsibility-Centered
Management (RCM). Units at all levels,
from departments to colleges, are held accountable for the cost of activities
for which they are responsible, even if these activities cross the boundaries
of departments, accounts, and majors.
ABC is different from
traditional accounting, which looks at expenditures and revenues within one or
more account structures, based on organizational reporting relationships
inherent in the financial chart of accounts.
The type of cost analysis is performed by sponsored research and fiscal
affairs offices is indirect cost recovery.
Administrative costs are shared across research activities based on an
agreed-upon indirect cost rate, which is itself based on complex weighting and
allocation schemes.
Since sponsored research and
service activities use institutional facilities, consume utilities, and require
administrative oversight with functions such as human resources administration,
it is important to consider these costs for sharing. In order to calculate “hidden” versus direct costs, micro-costing
models have been developed. Where the
Flashlight model incorporates only minimal calculations of hidden costs, some
implementations such as that done by the author at George Mason University are
more complex in their use of administrative cost-sharing. This discussion of the costs of online
courses will involve some relatively simple calculations of indirect costs (but
still difficult to gather data for).
The reader is again referred to Jenny (1996) and the NACUBO literature
for a more full discussion of micro-costing.
The Flashlight economic
model involves seven basic steps. As
stated in the Handbook, these are:
1 Identify your resource concerns and
the specific questions you want answered.
2. Identify your outputs.
3.
Identify the activities that
are required to produce your outputs.
4.
Identify the academic and
support units that participate in these activities.
5. Identify the resources these units
consume in their activities.
6. Calculate costs for these
activities.
7. Tally the costs of all activities to
arrive at your output costs
(Ehrmann and Milam, 1999, p. 11).
For the purposes of this
discussion of online courses, three sub-steps are added. Step 5, “identify the resources,” is broken
into two – for direct and indirect costs.
Step 6 is also broken into two, with additional data about enrollment
via the induced course load matrix. A
new step is also added to calculate revenue stream based on enrollment, tuition
and fees, and financial aid data. The
revised steps of a cost model for analyzing online courses now include the
following:
1. define the resource issues
2. choose outputs and
performance measures
3. document activities and
tasks
4. gather faculty and staff workload
data
5. collect data on direct costs
6. calculate data on hidden, indirect,
or shared administrative costs
7. gather data on enrollment
with the ICLM
8. calculate results for each activity
9. calculate revenue stream
10. summarize the results
Steps for a Cost Analysis
Model of Online Courses
1. Define the resource issues
Central to any model
development is the need to define the objectives. While we are focused on examining cost issues for online courses,
there are dozens of complex and informative models. It is impossible to create a single model which will meet a wide
variety of needs. Planners are well
served by establishing the resource allocation issue first, then building the
model. Once a model has been developed
and used for a specific question, new questions will arise. One needs to go through the model building
exercise again, rather than look for ways to simply tweak the existing model. While this may seem a luxury of time, it
prevents a type of planning myopia which sees only the solution, sometimes
without truly documenting and challenging the assumptions behind it.
The Flashlight Cost Analysis
Handbook recommends stating the resource allocation question directly in a few
sentences. For example, that an
institution wants to know whether it is
cheaper to offer an online section of a course than its traditional
counterpart. Cheaper will be
defined as sustaining higher enrollment without additional cost.
In examining online courses,
many questions beg comparison to their traditional counterparts and this needs
to be built into model development from the beginning. An online course may not have an on-campus
equivalent. It may be necessary to
benchmark against certain activities which make up the course, such as course
preparation time or working with students outside of class.
In choosing a resource issue
to study, pick something which lends itself to being broken down by activities
and within these tasks. If an
institution outsources online course development to a vendor, it may be
difficult to benchmark the costs by activity to a traditional course. A single fee per enrolled student may be
paid per semester to the vendor. While
the vendor supports the web server setup, course development, and
administrative tasks, these activities are often not broken out into data on
time or effort for an institution. Only
the activities which are under institutional control can be evaluated.
Whatever the question,
planners need to ensure that building a model will benefit the institution by answering
resource allocation questions of interest.
The Flashlight Handbook suggests that a mock version of a model be
created with simulated results. Does
the report tell administrators what they need to know to make decisions? If not, it is better to reframe the scope of
the model at the outset, rather than have to redefine it after much time and
ownership have already gone into its development.
2. Choose
outputs and performance measures
In the discussion of
resource questions, an example question was framed: whether it is cheaper to offer an online section of a course than its
traditional counterpart. The
next step is deciding how to measure costs.
What does it mean to be cheaper?
Is this the overall cost of offering an online course per enrolled student? Per student credit hour? Are costs calculated per semester or over
time? This is an important point, since
it often takes several semesters to develop an online course. Should the results somehow be amortized to
reflect true costs and benefits?
Lessons learned from the
four Flashlight case studies described in the Handbook suggest that one of the
standard performance indicators, student credit hours, is inadequate for
measuring costs in use of technology in teaching. This is because many implementations of a technology are used for
less than the traditional fifteen week course.
It is this very flexibility in course scheduling, with differentiated
stop and start dates and the ability to tailor course objectives to the
audience, which makes online courses so appealing. The calculation of credit hours in a fifteen week semester is a
traditional mindset which may or may not meet the needs of the resource
allocation question of interest.
An alternative presented in
the Handbook is weekly student course hours, the number of hours in which
students are expected to be engaged in directed, course-related learning
activities (different from time spent on homework assignments). For the traditional course which meets three
hours per week for fifteen weeks, this equates to forty-five hours per
student. Comparable to the measure of
weekly student contact hour which is used for calculating space utilization,
this measure is more helpful in measuring use.
For models of online course
costs which incorporate an assessment component as well, planners may wish to
use performance indicators such as cost per passing student or cost per
retained student. An online course may
potentially meet the need of many more students. How many of these students remained enrolled after the tenth
class day? Is there a higher drop-out
rate than the traditional class section?
Is there a lower pass rate? Or a
lower grade distribution? It is
impossible to expect that this analysis of course costs will be done in a
vacuum which does not take into account assessment issues. While this is not the intent of the model,
performance indicators should be chosen which address the true questions of
interest.
Since it takes significant
time to bring a concept for an online course to fruition, measuring course
costs over a single semester may be misleading. You may want to “amortize” course costs over several semesters or
years. Similarly, while it is interesting
to examine expenditures, this singular focus fails to take into account the
revenue side of the equation. Complex
models may be built which incorporate revenue data based on student enrollment,
calculated from tuition and fee charges by residency and student level and
incorporating standard models of financial aid and internal tuition
discounting. The performance measure of
revenue per online course is misleading if part of the revenue is made up of internal
funding with tuition discounting.
3. Document
activities and tasks
As the central feature of
activity-based cost models, the documentation of activities and tasks for
offering an online course is critical to a model’s success. This requires a certain assessment approach
which examines the nature of the teaching process and breaks the faculty role
into parts. A traditional class may
involve activities such as preparation, teaching, and administration. While these may be easily translated into
specific tasks, such as creating the syllabus or grading exams, it is this
definition of work and its equivalent expression in costs which is at the heart
of any costing model. Also, the
responses are never as straight forward as one might assume.
In determining the activities
and tasks involved in offering an online course, faculty and staff involved are
the best source of data. It is helpful
to ask what seem on the surface to be simple, open-ended, and innocuous questions. What do you do in this course? How do you handle the same types of tasks
you do in an on-campus class?
Working to gather data on
the many tasks which make up faculty work, one quickly learns that there is
little written documentation of effort.
Neither faculty nor staff keep logs of their activities. During an interview, they may think for the
first time of the tasks they performed to offer a course. Such planning can be very haphazard. Faculty members may introduce technology
into their classes over a period of time.
Online courses do not suddenly materialize into cyberspace. Faculty may have been introducing listservs,
email, and HTML documents into their classes for several years. A specific course may have evolved to the
point where so much Internet-based technology is used that it makes sense to
move it entirely online, but this is not necessarily a linear or rational
process. In understanding the
development and impact of online course development in an institution, one
should not be fooled into simplistic models of organizational theory, faculty
development, or curriculum design.
Here, as part of model
development, there is a great by-product of this process – documentation of
teaching roles. If planners are able to
document the many tasks and range of activities which make up the faculty and
staff support role, they will find that this a itself an interesting piece of
data. What exactly is the faculty
role? How is the faculty role changed
with offering online courses? These are
not simple questions. They are at the
center of costing models. Institutions
such as the University of Phoenix rely solely on part-time faculty. There is no attempt to perpetuate the
traditional faculty role. Should
schools create an instructional development function to share and pool resources
for online course development? This is
the model of the vendors such as UOL and ecollege.com (formerly Real
Education).
4. Gather faculty and staff workload data
While it may seem difficult
to define the activities and tasks which go into developing and offering an
online course, it is the gathering of actual workload data which is the most
frustrating for planners. No faculty
logs are kept. Staff members do not sit
with a list of their many projects, so that they can readily tell you how much
time they spent setting up a web server and what proportion of this effort was
devoted to the specific course. These
data are not kept because there are no rewards involved in keeping them. Resource allocation models rarely work with
more than the most gross approximation of faculty time.
This is not to say that some
institutions do not have faculty workload surveys in place or that department
chairs do not have some degree of control over their faculty members’
time. Yet these are accountability controls,
not intended for gathering actual data but for monitoring patterns of activity
over time.
As part of your model, you
may wish to ask faculty to complete a workload survey which documents the time
they spend on various activities. You
may want them to keep a log over several weeks to get actual data or you may be
willing to use estimates. In conducting
interviews with faculty about their online courses, you will be surprised to
learn that they do not have a clear sense of their time. Or it may be influenced by the activities of
the week you interview them. This
process of reflection may be as beneficial for them as it is for your model.
One recommendation from one
of the case studies in the Flashlight Handbook is that institutions rely on a
set of assumptions to guide the use of workload data. For a research or doctoral institution, faculty are expected to
teach at least two courses a semester, spend 25% of their time in
departmentally-sponsored research (unless they have external funding), and
spend another 10% or so in administrative duties such as advising and attending
faculty meetings. This suggests that
only 65% of their time and salary is devoted to instruction-related
activities. If faculty teach two
courses per semester or four per year, then this 65% must be distributed among
each of the four courses. See the
National Survey of Postsecondary Faculty (NSOPF), conducted by the National
Center for Education Statistics (NCES) for a source of national benchmarks in
faculty workload data (Kirshstein et al, 1997). The NSOPF survey documents the many ways to
collect complex workload data.
Another alternative is to
ask each faculty member to estimate the proportion of their instructional time
devoted to each course they teach.
Without data from logs, this is simply an estimate, better informed of
course with a listing of typical course activities and tasks to remind faculty
of just how many different roles they must juggle in the course of an academic
year.
Whether it is with actual
logs, estimates, or general assumptions, faculty workload data are essential
for any model of online course costs.
Similarly, there are many staff support roles and graduate teaching assistant
roles which need to be included. For
example, if a department secretary is involved in collecting grades and
distributing grade reports for a traditional course, how is this handled for an
online course? Is there decreased cost
because grades are posted online and given directly to the registrar? If these types of differences in
administration and support are not somehow taken into account, the calculation
of online versus traditional course costs will be misleading.
Using the faculty interview
as a source, it is important to find every interaction with support staff which
influences course activity and to build this into the model. This includes such tasks as computing staff
support for setting up space on a web server, library staff time spent teaching
a faculty member HTML in order for her to put up online documents, and departmental
evaluation and approval of the electronic or print syllabus.
5. Collect data on direct costs
Direct costs such as faculty compensation, including salary and
benefits prorated based on workload, are relatively easy to obtain from the
institutional research, budget, and human resource office. It is important to verify these data with
the faculty involved. Expenditure data
are less useful, not because they cannot be broken down by transaction for
actual course expenditures, but because there are often so few direct purchases
for a specific course. In one of the
case studies described in the Flashlight Handbook, faculty reported bearing the
cost of many small items themselves. It
is important to include these costs.
Departmental account reports
are a starting point. When meeting with
faculty to discuss any direct costs that may be related to their breakout of
activities and tasks, the department account report is only useful to a degree. Most are broken down into object code,
clusters of expenditures based on standard types such as travel or printing for
budgeting and allocation purposes. A
traditional class may involve $100 worth of copying, but this is not included
in any meaningful way in an existing report.
An individual faculty may have a code used by the copy center and may
estimate that copies made on a certain date were probably for a class. More likely these reports are by account
code and give no useful insight into costs.
This reality of reporting suggests that planners should put data
collection instruments in place before gathering data for their models. Give faculty members a worksheet to keep of
personal and departmental expenditures for the online class. Whenever possible, probe for places where
there may be missing data.
6.
Calculate data on hidden, indirect, or shared administrative costs
In its report Straight
Talk about College Costs & Prices, the Congressionally-sponsored
National Commission on the Cost of Higher Education discusses the “veil of
obscurity" which hangs over financial data. This is perhaps no more true than in regard to indirect or shared
administrative costs.
Direct expenditures only capture so much
data. Yet offering an online course in
department X may not cost the same as if it were offered in department Y,
solely because of departmental overhead.
Student enrollment is the product, however measured. All instructional activities exist in order
to support enrollment. All
instruction-related costs must somehow be taken into account in building a cost
model for the online course.
For example, department X may offer 50
different course sections in a semester, and department Y offers 40. The departmental staff includes a chair and
a secretary. Neither of these staff may
spend any time directly related to the online course, but they support the
activity in an indirect way via monitoring, oversight, personnel matters,
etc. Somehow these costs need to be
distributed among instructional activities.
This may be done with various allocation schemes, such as by student
credit hour or by individual course.
Since the overhead of monitoring the success of enrollment is often at
the course level, online course costing models may want to allocate
departmental costs by the course.
Therefore, department X’s chair and staff
compensation costs are allocated to each of the 50 courses, department Y’s to
its 40 courses. If the chair and staff
salaries are relatively equal, department X will end up costing less per course
in administrative overhead. Similar allocation
schemes need to be built in at the dean’s level and at the institutional
level. These data show that not all
departments and schools are equally prepared to bear the cost of an online
course. It may be much more economical
in terms of overhead to offer an online course in English, where there are many
courses and a relatively thin departmental support team, than to offer courses
in Anthropology, where there are far fewer courses. The circumstances are always different with different
disciplinary structures at institutions. The point is that these support costs
are real and need to be included in resource allocation models.
In
addition to administrative overhead, which is treated much more completely in
Jenny (1996), Hyatt (1983), and Meisinger and Dubeck (1984),
there are other hidden costs to consider with online courses – including space
and computing.
Much is made of cost savings
realized because online courses do not require bricks and mortar. While it is true that classroom space is not
required, classroom space is not the largest component of facilities room use,
simply the most recognizable. Faculty
office, instructional support, clerical support, and computing facilities also
need to be included in the use of space by the online course.
In determining the cost of
using space on campus, there are many models.
The National Cost Commission report suggests the need, based on the work
of Gordon Winston, to include opportunity costs in examination of tuition price
and subsidy. One possible model is to
express opportunity costs as the lost revenue which could have been earned if
an institution had rented the space used by the course at fair market
value. This calculation also builds in
some of the cost of depreciation and maintenance, other facility costs not
often taken into account. Regardless of
whether an online course uses classroom space, models of online costs versus
their traditional counterparts need to include hidden facilities costs. Many traditional courses will have the same
or greater costs, so it may be a wash.
However, no course costing model is complete which does not include some
assumptions about space utilization. If
anything, it is important to use these data to show that online courses provide
substantive savings based on their decreased use of space, a claim that while
intuitively true needs data to support it.
Other computing support
costs should be included and it is here that the planner may find the greatest
dearth of data or meaningful allocation scheme. An online course uses a listserv. During a given semester, there may be 150 listservs in
operation. What is the course’s share
of this cost?
A series of questions
follow. What server is used to house
the listserv? What did the server cost
to purchase or upgrade and what does it cost to maintain in terms of utilities
and staffing? What activities does the
server support and how might these be prorated to allocate the server costs? Each technology used in online courses
should be scrutinized in this manner.
This includes email, listservs, newsgroups, telnet, threaded discussion
rooms, chat rooms, MUDs and MOOs, administrative information systems, web
servers, Java simulations, collaboration software, audio/video delivery, and
database software such as Perl, Cold Fusion, or Active Server Pages, etc. In many cases, planners will find that there
are no existing studies which document the costs of any of these services. They are all ripe for activity-based
costing. Faced with this problem,
rather than build incomplete models or models that rely on estimates that are
little supported with data, recognize that your model adds value by beginning
to help document that these hidden support costs do exist.
Of course, if faculty set up
their own web server, or if the use of technology is a first in setting up
services for an online course, the costs are more readily identified. Be wary of making a single course bear these
costs, though. Amortization schemes are
in order which spread these costs over time.
Online courses do not suddenly build themselves. Pay attention to the evolution of technology
in a department’s courses and the ways in which this lends itself to online
course development. Resource allocation
models need to somehow incorporate this development process.
Other
computing costs to be included in the model are the computer, printers, and
network used by the faculty, staff, and/or graduate teaching assistant in the
course. Some estimates of use may be
made, perhaps comparable to the estimate of faculty workload. For example, 65% of activities may be
instruction-related, therefore 65% of the PC is instruction related. Of this same 65%, the faculty member
teachings four courses per academic year.
In this case, 16% of the amortized cost for purchasing the PC and 16% of
direct software and other computing costs may be allocated to each course.
7. Gather data on enrollment with the ICLM
In understanding costs, most
performance indicators are built around enrollment. These include weekly student contact hours, passing student,
student credit hour, headcount, full-time equivalent student, and other
calculations. Much is learned by
knowing class enrollments, but this is only a starting point. If revenue is to be considered, the induced
course load matrix or ICLM must be part of the model.
The administrative
information system structure of data used by higher education traditionally
includes one record per student per course.
Therefore, if a student takes five three credit hour classes, whether or
not they meet online or on campus, there will be five records created in the
student database. Since one of these is
for a specific course, it is easy to calculate that 20% of the revenue generated
by a single student’s tuition and fees should be counted for the course.
This simple example is
repeated many thousands of times to estimate what proportion of all students
course activity goes to the single online course being studied. If there are 100 students enrolled in the
online course, and they all take 5 courses each, then course serves the
equivalent of 20 full-time equivalent (FTE) students. If the average full-time tuition and fees charge for a semester
is $2,000, it may be reasonably estimated that the course earned $40,000 in revenue.
The ICLM has many more benefits than this type of calculation. Most useful is the measurement of departmental
consumption and contribution. A
department offers classes that are taken by many different students, not just
its own majors. When non-majors take
its courses, the department is contributing to other departments. When performance measures are based solely
on majors, the department suffers since it has a service role that is not being
taken into account. Similarly, a
department’s majors take many courses outside of the department, making it a
consumer of other departments offerings.
This balance of consumption and contribution in credit hour course
activity is the battleground for departmental resource allocation.
In estimating the cost of
online courses, do not fail to address the question of whether the online
course contributes to the department’s role in consumption or
contribution. If a department continues
to serve more outside students, this should be part of resource allocation
decisions. Such an argument may help a
department get funding for an additional faculty position. The flip side of this perceived service and
consumer role is faculty workload. With
online courses, it is possible to serve more student enrollment with existing
resources, changing the departmental dynamic.
It is important to balance the competing tensions of service,
consumption, faculty workload, and enrollment when analyzing online course
costs. The ICLM is a very useful tool
for analyzing these tensions. In the
past, it has been very difficult to portray the hundreds of thousands of cells
and hundreds of possible relationships between units. With web database applications, data marts can now portray these
results in a way which can be understood and used by chairs and deans in their
battles over resource allocation.
8.
Calculate results for each activity
After data are gathered on
the types of activities and tasks which are involved in offering an online
course, data are collected about faculty and staff workload. These are then prorated against compensation
(salaries and benefits). Any direct
costs associated with the online course are documented, even those born out of
pocket by the faculty member (for future reference). If at all possible, administrative overhead for at least the department
level should be estimated. Dean’s level
and institutional administrative cost sharing may also be calculated for any
instruction-related expenditures. These
indirect costs may be allocated in various ways, perhaps most simply by the
number of courses within each unit of analysis.
This resulting total cost
for the online course is used to calculate the performance indicator of
interest. This often begins with total
cost per online course and routinely moves to cost per weekly student course
hour.
These costs may also be
calculated based on each activity, such as course preparation, teaching, and administrative
tasks. This is the first of the many
cost “drivers” which may be tweaked as planners analyze a model. For example, an online course may involve
many more hours in course preparation than a traditional course. In overall costs, the online course may be
more expensive for this reason, because it consumes more compensation. The next time the course is offered,
however, this activity is not nearly as labor intensive, driving the cost of
course preparation down and making the online course more efficient than its
traditional counterpart.
Some of the other cost
drivers which may be built into the model include: faculty compensation – what
if part-time faculty are used to teach the course; using a vendor to handle the
online technology; offering the course in a department where there is less
administrative overhead; using an equipment trust fund or grant to pay for new
computers instead of building these into the course costs; distributing online
documents via CD-Rom; and using less classroom and office space. Each of these cost drivers may be built
into the model and may be tweaked to get different results. It is necessary to remember this when
analyzing the results the first time data for the model are put together. For while it may appear at first that an
online course is equally expensive to offer, what drivers might effect the
result? If another, less expensive faculty
member taught the course – would the cost go down or would it go up because
this person had to spend more time getting up to speed on the technology? Does it truly cost less if the class never
meets on campus or is it less expensive to meet several times on campus because
this builds a relationship between the instructor and the students and improves
their retention and grade distribution?
These are only a few of the many questions which should be asked of
models.
9. Calculate
revenue stream
In calculating the amount of revenue generated by an online course’s
enrollment, based on the ICLM data, the results also need to be adjusted based
on financial aid. Just as the
institution’s course file is used to document the total number of classes taken
by students in the course, the financial aid database is also necessary to this
calculation. However, of all the data
files available for institutions, financial aid may be the most complex and
most easy to misinterpret.
In the best case scenario,
financial aid data for the students enrolled in an online course are used to
calculate what actual tuition and fees revenue charge was paid. This is the net of the tuition and fees
charges after any internal tuition discounting or waiver which may be in
place. For example, an employee may be
enrolled in the course. While the
person should be included in measures of faculty workload and costs, she or he
may have a tuition waiver as a benefit of employment so that there is no
associated revenue.
For most purposes, it is
adequate to estimate the percent of enrollment by course level with waivers and
with tuition discounts. The average
tuition discount per student level or course level may be calculated by the
financial aid office, perhaps as part of routine reports for admissions guides
or the institutional fact book. With
this estimate, a modified revenue stream for the online course is calculated
that takes into account the very real practice of tuition discounting and is
based on the tuition and fees charges per student level and residency of those
enrolled in the class (prorated by their total number of courses).
10. Summarize the results
This step brings the cost
and revenue components of the model together to calculate the true cost of an
online course, using the performance measure of choice. It is here, though, that planners often
face a dilemma – how to interpret the results.
For every performance indicator may be interpreted in two directions. A lower cost for the online course, the
result for example of increased enrollment, may be seen as cost-effective use
of technology. If too low, the same
result may be viewed as inadequate academic support.
The model results may show
that there is a high cost in terms of faculty compensation for the activity of
course preparation, but that this will decrease significantly the next time the
online course is offered because the faculty member will only have to update
web content. Yet where is the
displacement in effort going to take place. Will the faculty member then spend
more time conducting departmental research?
If they are already engaging in the agreed upon percentage of time for
this activity, what is to stop them from spending more time in research,
especially if there are no data to track their effort? Perhaps the time originally spent on course
preparation should be shifted to some aspect of working with students online in
order to improve their retention rate or grade distribution. There are many more such questions which
arise from model building. Building a
model like this raises more questions than it answers, but this is not in and
of itself a negative result. Rather, it
forces planners and administrators to document and question their
assumptions.
Conclusions
It is perhaps in documenting
and questioning their assumptions that models may best serve planners. So often, they are met with difficulties in
gathering data to support the model.
Some of the most important by-products of this planning process are information
about the changing nature of faculty roles in online teaching and a better
understanding of the cost drivers which impact a particular performance
measure.
There is much more to be
said about this type of model building.
This paper has involved a review of the new Flashlight Cost Analysis
Handbook and its approach to models for evaluating resource use in teaching
with technology. The Flashlight model
has been applied specifically to the topic of online courses and lends itself
well to this purpose.
Clearly, one of the greatest
hurdles for planners is in gathering the data they need about faculty workload,
administrative cost sharing, and hidden and indirect costs. Yet research and practice standards by
NACUBO and NCES have much to offer the novice and advanced modeler in this
arena. What is most critical to the
success of helping institutions prepare for their online presence is a sense of
what is possible with resource planning models. By following the seven basic steps of the Flashlight Handbook or
the expanded ten steps discussed herein, planners can walk through the maze of
complex issues which face them and create models that bring these competing
tensions and priorities of academic management to life. We do our institutions and ourselves a disservice
if we fail to use this tool at hand to understand the dramatic changes which engulf
us as we enter the 21st century.
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