short answers (300 words, less than one page) - Reading
Read the article carefully and then answer the 2 questions
Defining software quality
To begin this course, this reading introduces you to the broader ideas behind
the topic of software quality and provides some initial perspectives on why
quality is hard to measure, and how software engineers have approached this
tough measurement problem. You will also learn that there is no single,
universal definition of software quality, and the concept is used with varying
meanings in different situations.
To read
Each week of the semester, you will have a reading assignment to complete
that includes a brief written response to two questions based on the reading.
• [required] Robert Glass. The link between software quality and
software maintenance
. Software Conflict: Essays on the Art and Science of Software
Engineering, Prentice-Hall, 1991, pp. 49-51.
• [required] Robert Glass. Can you MANAGE quality into a software
product?
Software Conflict: Essays on the Art and Science of Software
Engineering, Prentice-Hall, 1991, pp. 147-149.
• [required] Roger S. Pressman. Chapter 14: Quality Concepts
. Software Engineering: A Practitioners Approach, 7th ed.,
McGraw-Hill, 2010, pp. 398-415 [can also use 8th edition].
To turn in
Prepare a brief (no more than one page) written answer to the following two
questions. Write up your answer using MS Word or LaTex. One well-
presented paragraph for each question is sufficient.
1. Robert Glass does not include all of the quality attributes that are in
McCalls list of quality factors. Do you believe the extra attributes in
McCalls list are necessary for quality software, or is Glass
definition sufficient? Justify your answer.
2. In Glass definition, which single attribute do you believe is most
important, and why?
Defining software quality
To read
To turn in
The drumbeat for improved software quality began in earnest as softwarebecame increasingly integrated in every facet of our lives. By the 1990s,major corporations recognized that billions of dollars each year were be-
ing wasted on software that didn’t deliver the features and functionality that were
promised. Worse, both government and industry became increasingly concerned
that a major software fault might cripple important infrastructure, costing tens
of billions more. By the turn of the century, CIO Magazine [Lev01] trumpeted
the headline, “Let’s Stop Wasting $78 Billion a Year,” lamenting the fact that
“American businesses spend billions for software that doesn’t do what it’s sup-
posed to do.” InformationWeek [Ric01] echoed the same concern:
Despite good intentions, defective code remains the hobgoblin of the software indus-
try, accounting for as much as 45\% of computer-system downtime and costing U.S.
companies about $100 billion last year in lost productivity and repairs, says the
Standish Group, a market research firm. That doesn’t include the cost of losing angry
customers. Because IT shops write applications that rely on packaged infrastructure
software, bad code can wreak havoc on custom apps as well. . . .
Just how bad is bad software? Definitions vary, but experts say it takes only three or
four defects per 1,000 lines of code to make a program perform poorly. Factor in that most
programmers inject about one error for every 10 lines of code they write, multiply that by
the millions of lines of code in many commercial products, then figure it costs software
vendors at least half their development budgets to fix errors while testing. Get the picture?
398
C H A P T E R
14 QUALITYCONCEPTS
K E Y
C O N C E P T S
cost of quality . .407
good enough . . .406
liability . . . . . .410
management
actions . . . . . . .411
quality . . . . . . .399
quality
dilemma . . . . . .406
quality
dimensions . . . .401
quality factors .402
quantitative
view . . . . . . . .405
risks . . . . . . . .409
security . . . . . .410
What is it? The answer isn’t as easy
as you might think. You know quality
when you see it, and yet, it can be an
elusive thing to define. But for com-
puter software, quality is something that we must
define, and that’s what I’ll do in this chapter.
Who does it? Everyone—software engineers,
managers, all stakeholders—involved in the
software process is responsible for quality.
Why is it important? You can do it right, or you
can do it over again. If a software team stresses
quality in all software engineering activities, it
reduces the amount of rework that it must do.
That results in lower costs, and more importantly,
improved time-to-market.
Q U I C K
L O O K
What are the steps? To achieve high-quality
software, four activities must occur: proven soft-
ware engineering process and practice, solid
project management, comprehensive quality
control, and the presence of a quality assurance
infrastructure.
What is the work product? Software that
meets its customer’s needs, performs accurately
and reliably, and provides value to all who
use it.
How do I ensure that I’ve done it right? Track
quality by examining the results of all quality
control activities, and measure quality by exam-
ining errors before delivery and defects
released to the field.
pre75977_ch14.qxd 11/27/08 5:51 PM Page 398
C H A P T E R 1 4 Q U A L I T Y C O N C E P T S 399
In 2005, ComputerWorld [Hil05] lamented that “bad software plagues nearly every
organization that uses computers, causing lost work hours during computer down-
time, lost or corrupted data, missed sales opportunities, high IT support and mainte-
nance costs, and low customer satisfaction. A year later, InfoWorld [Fos06] wrote
about the “the sorry state of software quality” reporting that the quality problem had
not gotten any better.
Today, software quality remains an issue, but who is to blame? Customers blame
developers, arguing that sloppy practices lead to low-quality software. Developers
blame customers (and other stakeholders), arguing that irrational delivery dates and
a continuing stream of changes force them to deliver software before it has been fully
validated. Who’s right? Both—and that’s the problem. In this chapter, I consider soft-
ware quality as a concept and examine why it’s worthy of serious consideration
whenever software engineering practices are applied.
1 4 . 1 W H AT I S Q U A L I T Y ?
In his mystical book, Zen and the Art of Motorcycle Maintenance, Robert Persig [Per74]
commented on the thing we call quality:
Quality . . . you know what it is, yet you don’t know what it is. But that’s self-contradictory.
But some things are better than others; that is, they have more quality. But when you try
to say what the quality is, apart from the things that have it, it all goes poof! There’s noth-
ing to talk about. But if you can’t say what Quality is, how do you know what it is, or how
do you know that it even exists? If no one knows what it is, then for all practical purposes
it doesn’t exist at all. But for all practical purposes it really does exist. What else are the
grades based on? Why else would people pay fortunes for some things and throw others
in the trash pile? Obviously some things are better than others . . . but what’s the better-
ness? . . . So round and round you go, spinning mental wheels and nowhere finding any-
place to get traction. What the hell is Quality? What is it?
Indeed—what is it?
At a somewhat more pragmatic level, David Garvin [Gar84] of the Harvard Busi-
ness School suggests that “quality is a complex and multifaceted concept” that can
be described from five different points of view. The transcendental view argues (like
Persig) that quality is something that you immediately recognize, but cannot explic-
itly define. The user view sees quality in terms of an end user’s specific goals. If a
product meets those goals, it exhibits quality. The manufacturer’s view defines qual-
ity in terms of the original specification of the product. If the product conforms to the
spec, it exhibits quality. The product view suggests that quality can be tied to inher-
ent characteristics (e.g., functions and features) of a product. Finally, the value-based
view measures quality based on how much a customer is willing to pay for a prod-
uct. In reality, quality encompasses all of these views and more.
Quality of design refers to the characteristics that designers specify for a product.
The grade of materials, tolerances, and performance specifications all contribute to
the quality of design. As higher-grade materials are used, tighter tolerances and
What are the different
ways in which quality
can be viewed?
pre75977_ch14.qxd 11/27/08 5:51 PM Page 399
greater levels of performance are specified, the design quality of a product increases,
if the product is manufactured according to specifications.
In software development, quality of design encompasses the degree to which the
design meets the functions and features specified in the requirements model. Quality
of conformance focuses on the degree to which the implementation follows the
design and the resulting system meets its requirements and performance goals.
But are quality of design and quality of conformance the only issues that software
engineers must consider? Robert Glass [Gla98] argues that a more “intuitive” rela-
tionship is in order:
user satisfaction ! compliant product good quality delivery within budget and schedule
At the bottom line, Glass contends that quality is important, but if the user isn’t
satisfied, nothing else really matters. DeMarco [DeM98] reinforces this view when he
states: “A product’s quality is a function of how much it changes the world for the
better.” This view of quality contends that if a software product provides substantial
benefit to its end users, they may be willing to tolerate occasional reliability or per-
formance problems.
1 4 . 2 S O F T WA R E Q U A L I T Y
Even the most jaded software developers will agree that high-quality software is an
important goal. But how do we define software quality? In the most general sense,
software quality can be defined1 as: An effective software process applied in a manner
that creates a useful product that provides measurable value for those who produce it
and those who use it.
There is little question that the preceding definition could be modified or extended
and debated endlessly. For the purposes of this book, the definition serves to
emphasize three important points:
1. An effective software process establishes the infrastructure that supports any
effort at building a high-quality software product. The management aspects
of process create the checks and balances that help avoid project chaos—a
key contributor to poor quality. Software engineering practices allow the
developer to analyze the problem and design a solid solution—both critical
to building high-quality software. Finally, umbrella activities such as change
management and technical reviews have as much to do with quality as any
other part of software engineering practice.
2. A useful product delivers the content, functions, and features that the end
user desires, but as important, it delivers these assets in a reliable, error-free
400 P A R T T H R E E Q U A L I T Y M A N A G E M E N T
uote:
“People forget how
fast you did a job—
but they always
remember how
well you did it.”
Howard Newton
1 This definition has been adapted from [Bes04] and replaces a more manufacturing-oriented view
presented in earlier editions of this book.
pre75977_ch14.qxd 11/27/08 5:51 PM Page 400
way. A useful product always satisfies those requirements that have been
explicitly stated by stakeholders. In addition, it satisfies a set of implicit
requirements (e.g., ease of use) that are expected of all high-quality software.
3. By adding value for both the producer and user of a software product, high-
quality software provides benefits for the software organization and the end-
user community. The software organization gains added value because
high-quality software requires less maintenance effort, fewer bug fixes, and
reduced customer support. This enables software engineers to spend more
time creating new applications and less on rework. The user community
gains added value because the application provides a useful capability in
a way that expedites some business process. The end result is (1) greater
software product revenue, (2) better profitability when an application
supports a business process, and/or (3) improved availability of information
that is crucial for the business.
14.2.1 Garvin’s Quality Dimensions
David Garvin [Gar87] suggests that quality should be considered by taking a multidi-
mensional viewpoint that begins with an assessment of conformance and termi-
nates with a transcendental (aesthetic) view. Although Garvin’s eight dimensions of
quality were not developed specifically for software, they can be applied when soft-
ware quality is considered:
Performance quality. Does the software deliver all content, functions, and
features that are specified as part of the requirements model in a way that
provides value to the end user?
Feature quality. Does the software provide features that surprise and
delight first-time end users?
Reliability. Does the software deliver all features and capability without
failure? Is it available when it is needed? Does it deliver functionality that is
error-free?
Conformance. Does the software conform to local and external software
standards that are relevant to the application? Does it conform to de facto
design and coding conventions? For example, does the user interface con-
form to accepted design rules for menu selection or data input?
Durability. Can the software be maintained (changed) or corrected
(debugged) without the inadvertent generation of unintended side effects?
Will changes cause the error rate or reliability to degrade with time?
Serviceability. Can the software be maintained (changed) or corrected
(debugged) in an acceptably short time period? Can support staff acquire all
information they need to make changes or correct defects? Douglas Adams
[Ada93] makes a wry comment that seems appropriate here: “The difference
C H A P T E R 1 4 Q U A L I T Y C O N C E P T S 401
pre75977_ch14.qxd 11/27/08 5:51 PM Page 401
between something that can go wrong and something that can’t possibly go
wrong is that when something that can’t possibly go wrong goes wrong it
usually turns out to be impossible to get at or repair.”
Aesthetics. There’s no question that each of us has a different and very
subjective vision of what is aesthetic. And yet, most of us would agree that
an aesthetic entity has a certain elegance, a unique flow, and an obvious
“presence” that are hard to quantify but are evident nonetheless. Aesthetic
software has these characteristics.
Perception. In some situations, you have a set of prejudices that will influ-
ence your perception of quality. For example, if you are introduced to a soft-
ware product that was built by a vendor who has produced poor quality in
the past, your guard will be raised and your perception of the current soft-
ware product quality might be influenced negatively. Similarly, if a vendor
has an excellent reputation, you may perceive quality, even when it does not
really exist.
Garvin’s quality dimensions provide you with a “soft” look at software quality.
Many (but not all) of these dimensions can only be considered subjectively. For this
reason, you also need a set of “hard” quality factors that can be categorized in two
broad groups: (1) factors that can be directly measured (e.g., defects uncovered dur-
ing testing) and (2) factors that can be measured only indirectly (e.g., usability or
maintainability). In each case measurement must occur. You should compare the
software to some datum and arrive at an indication of quality.
14.2.2 McCall’s Quality Factors
McCall, Richards, and Walters [McC77] propose a useful categorization of factors
that affect software quality. These software quality factors, shown in Figure 14.1,
focus on three important aspects of a software product: its operational characteris-
tics, its ability to undergo change, and its adaptability to new environments.
Referring to the factors noted in Figure 14.1, McCall and his colleagues provide
the following descriptions:
Correctness. The extent to which a program satisfies its specification and fulfills the
customer’s mission objectives.
Reliability. The extent to which a program can be expected to perform its intended func-
tion with required precision. [It should be noted that other, more complete definitions of
reliability have been proposed (see Chapter 25).]
Efficiency. The amount of computing resources and code required by a program to
perform its function.
Integrity. Extent to which access to software or data by unauthorized persons can be
controlled.
Usability. Effort required to learn, operate, prepare input for, and interpret output of a
program.
402 P A R T T H R E E Q U A L I T Y M A N A G E M E N T
pre75977_ch14.qxd 11/27/08 5:51 PM Page 402
Maintainability. Effort required to locate and fix an error in a program. [This is a very
limited definition.]
Flexibility. Effort required to modify an operational program.
Testability. Effort required to test a program to ensure that it performs its intended
function.
Portability. Effort required to transfer the program from one hardware and/or software
system environment to another.
Reusability. Extent to which a program [or parts of a program] can be reused in other
applications—related to the packaging and scope of the functions that the program
performs.
Interoperability. Effort required to couple one system to another.
It is difficult, and in some cases impossible, to develop direct measures2 of these
quality factors. In fact, many of the metrics defined by McCall et al. can be measured
only indirectly. However, assessing the quality of an application using these factors
will provide you with a solid indication of software quality.
14.2.3 ISO 9126 Quality Factors
The ISO 9126 standard was developed in an attempt to identify the key quality
attributes for computer software. The standard identifies six key quality attributes:
Functionality. The degree to which the software satisfies stated needs as
indicated by the following subattributes: suitability, accuracy, interoperability,
compliance, and security.
Reliability. The amount of time that the software is available for use as indi-
cated by the following subattributes: maturity, fault tolerance, recoverability.
C H A P T E R 1 4 Q U A L I T Y C O N C E P T S 403
PRODUCT OPERATION
PRODUCT TRANSITIONPRODUCT REVISION
Correctness Usability Efficiency
Reliability Integrity
Maintainability
Flexibility
Testability
Portability
Reusability
Interoperability
FIGURE 14.1
McCall’s
software
quality factors
uote:
“The bitterness
of poor quality
remains long after
the sweetness of
meeting the
schedule has been
forgotten.”
Karl Weigers
(unattributed
quote)
2 A direct measure implies that there is a single countable value that provides a direct indication of
the attribute being examined. For example, the “size” of a program can be measured directly by
counting the number of lines of code.
pre75977_ch14.qxd 11/27/08 5:51 PM Page 403
Usability. The degree to which the software is easy to use as indicated by
the following subattributes: understandability, learnability, operability.
Efficiency. The degree to which the software makes optimal use of system
resources as indicated by the following subattributes: time behavior, resource
behavior.
Maintainability. The ease with which repair may be made to the software as
indicated by the following subattributes: analyzability, changeability, stability,
testability.
Portability. The ease with which the software can be transposed from one
environment to another as indicated by the following subattributes: adapt-
ability, installability, conformance, replaceability.
Like other software quality factors discussed in the preceding subsections, the ISO
9126 factors do not necessarily lend themselves to direct measurement. However,
they do provide a worthwhile basis for indirect measures and an excellent checklist
for assessing the quality of a system.
14.2.4 Targeted Quality Factors
The quality dimensions and factors presented in Sections 14.2.1 and 14.2.2 focus on
the software as a whole and can be used as a generic indication of the quality of an
application. A software team can develop a set of quality characteristics and associ-
ated questions that would probe3 the degree to which each factor has been satisfied.
For example, McCall identifies usability as an important quality factor. If you were
asked to review a user interface and assess its usability, how would you proceed?
You might start with the subattributes suggested by McCall—understandability,
learnability, and operability—but what do these mean in a pragmatic sense?
To conduct your assessment, you’ll need to address specific, measurable (or at
least, recognizable) attributes of the interface. For example [Bro03]:
Intuitiveness. The degree to which the interface follows expected usage patterns
so that even a novice can use it without significant training.
• Is the interface layout conducive to easy understanding?
• Are interface operations easy to locate and initiate?
• Does the interface use a recognizable metaphor?
• Is input specified to economize key strokes or mouse clicks?
• Does the interface follow the three golden rules? (Chapter 11)
• Do aesthetics aid in understanding and usage?
404 P A R T T H R E E Q U A L I T Y M A N A G E M E N T
uote:
“Any activity
becomes creative
when the doer
cares about doing
it right, or better.”
John Updike
Although it’s tempting
to develop quantitative
measures for the
quality factors noted
here, you can also
create a simple
checklist of attributes
that provide a solid
indication that the
factor is present.
3 These characteristics and questions would be addressed as part of a software review (Chapter 15).
pre75977_ch14.qxd 11/27/08 5:51 PM Page 404
Efficiency. The degree to which operations and information can be located or
initiated.
• Does the interface layout and style allow a user to locate operations and
information efficiently?
• Can a sequence of operations (or data input) be performed with an economy
of motion?
• Are output data or content presented so that it is understood immediately?
• Have hierarchical operations been organized in a way that minimizes the
depth to which a user must navigate to get something done?
Robustness. The degree to which the software handles bad input data or inap-
propriate user interaction.
• Will the software recognize the error if data at or just outside prescribed
boundaries is input? More importantly, will the software continue to operate
without failure or degradation?
• Will the interface recognize common cognitive or manipulative mistakes and
explicitly guide the user back on the right track?
• Does the interface provide useful diagnosis and guidance when an error
condition (associated with software functionality) is uncovered?
Richness. The degree to which the interface provides a rich feature set.
• Can the interface be customized to the specific needs of a user?
• Does the interface provide a macro capability that enables a user to identify a
sequence of common operations with a single action or command?
As the interface design is developed, the software team would review the design
prototype and ask the questions noted. If the answer to most of these questions is
“yes,” it is likely that the user interface exhibits high quality. A collection of questions
similar to these would be developed for each quality factor to be assessed.
14.2.5 The Transition to a Quantitative View
In the preceding subsections, I have presented a variety of qualitative factors for the
“measurement” of software quality. The software engineering community strives to
develop precise measures for software quality and is sometimes frustrated by the
subjective nature of the activity. Cavano and McCall [Cav78] discuss this situation:
The determination of quality is a key factor in every day events—wine tasting contests,
sporting events [e.g., gymnastics], talent contests, etc. In these situations, quality is
judged in the most fundamental and direct manner: side by side comparison of objects
under identical conditions and with predetermined concepts. The wine may be judged
according to clarity, color, bouquet, taste, etc. However, this type of judgment is very sub-
jective; to have any value at all, it must be made by an expert.
C H A P T E R 1 4 Q U A L I T Y C O N C E P T S 405
pre75977_ch14.qxd 11/27/08 5:51 PM Page 405
Subjectivity and specialization also apply to determining software quality. To help
solve this problem, a more precise definition of software quality is needed as well as a
way to derive quantitative measurements of software quality for objective analysis. . . .
Since there is no such thing as absolute knowledge, one should not expect to measure
software quality exactly, for every measurement is partially imperfect. Jacob Bronkowski
described this paradox of knowledge in this way: “Year by year we devise more precise
instruments with which to observe nature with more fineness. And when we look at the
observations we are discomfited to see that they are still fuzzy, and we feel that they are
as uncertain as ever.”
In Chapter 23, I’ll present a set of software metrics that can be applied to the quan-
titative assessment of software quality. In all cases, the metrics represent indirect
measures; that is, we never really measure quality but rather some manifestation of
quality. The complicating factor is the precise relationship between the variable that
is measured and the quality of software.
1 4 . 3 T H E S O F T WA R E Q U A L I T Y D I L E M M A
In an interview [Ven03] published on the Web, Bertrand Meyer discusses what I call
the quality dilemma:
If you produce a software system that has terrible quality, you lose because no one will
want to buy it. If on the other hand you spend infinite time, extremely large effort, and
huge sums of money to build the absolutely perfect piece of software, then it’s going to
take so long to complete and it will be so expensive to produce that you’ll be out of busi-
ness anyway. Either you missed the market window, or you simply exhausted all your
resources. So people in industry try to get to that magical middle ground where the prod-
uct is good enough not to be rejected right away, such as during evaluation, but also not
the object of so much perfectionism and so much work that it would take too long or cost
too much to complete.
It’s fine to state that software engineers should strive to produce high-quality
systems. It’s even better to apply good practices in your attempt to do so. But the
situation discussed by Meyer is real life and represents a dilemma for even the best
software engineering organizations.
14.3.1 “Good Enough” Software
Stated bluntly, if we are to accept the argument made by Meyer, is it acceptable
to produce “good enough” software? The answer to this question must be “yes,”
because major software companies do it every day. They create software with known
bugs and deliver it to a broad population of end users. They recognize that some of
the functions and features delivered in Version 1.0 may not be of the highest quality
and plan for improvements in Version 2.0. They do this knowing that some cus-
tomers will complain, but they recognize that time-to-market may trump better qual-
ity as long as the delivered product is “good enough.”
406 P A R T T H R E E Q U A L I T Y M A N A G E M E N T
When you’re faced
with the quality
dilemma (and
everyone is faced
with it at one time
or another), try to
achieve balance—
enough effort to
produce acceptable
quality without burying
the project.
pre75977_ch14.qxd 11/27/08 5:51 PM Page 406
Exactly what is “good enough”? Good enough software delivers high-quality func-
tions and features that users desire, but at the same time it delivers other more
obscure or specialized functions and features that contain known bugs. The soft-
ware vendor hopes that the vast majority of end users will overlook the bugs because
they are so happy with other application functionality.
This idea may resonate with many readers. If you’re one of them, I can only ask
you to consider some of the arguments against “good enough.”
It is true that “good enough” may work in some application domains and for a few
major software companies. After all, if a company has a large marketing budget and
can convince enough people to buy version 1.0, it has succeeded in locking them in.
As I noted earlier, it can argue that it will improve quality in subsequent versions. By
delivering a good enough version 1.0, it has cornered the market.
If you work for a small company be wary of this philosophy. When you deliver a
good enough (buggy) product, you risk permanent damage to your company’s repu-
tation. You may never get a chance to deliver version 2.0 because bad buzz may
cause your sales to plummet and your company to fold.
If you work in certain application domains (e.g., real-time embedded software) or
build application software that is integrated with hardware (e.g., automotive soft-
ware, telecommunications software), delivering software with known bugs can be
negligent and open your company to expensive litigation. In some cases, it can even
be criminal. No one wants good enough aircraft avionics software!
So, proceed with caution if you believe that “good enough” is a short cut that can
solve your software quality problems. It can work, but only for a few and only in a
limited set of application domains.4
14.3.2 The Cost of Quality
The argument goes something like this—we know that quality is important, but it costs
us time and money—too much time and money to get the level of software quality we
really want. On its face, this argument seems reasonable (see Meyer’s comments ear-
lier in this section). There is no question that quality has a cost, but lack of quality also
has a cost—not only to end users who must live with buggy software, but also to the
software organization that has built and must maintain it. The real question is this:
which cost should we be worried about? To answer this question, you must understand
both the cost of achieving quality and the cost of low-quality software.
The cost of quality includes all costs incurred in the pursuit of quality or in per-
forming quality-related activities and the downstream costs of lack of quality. To
understand these …
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https://www.fnu.edu/library/
In order to
n that draws upon the theoretical reading to explain and contextualize the design choices. Be sure to directly quote or paraphrase the reading
ce to the vaccine. Your campaign must educate and inform the audience on the benefits but also create for safe and open dialogue. A key metric of your campaign will be the direct increase in numbers.
Key outcomes: The approach that you take must be clear
Mechanical Engineering
Organic chemistry
Geometry
nment
Topic
You will need to pick one topic for your project (5 pts)
Literature search
You will need to perform a literature search for your topic
Geophysics
you been involved with a company doing a redesign of business processes
Communication on Customer Relations. Discuss how two-way communication on social media channels impacts businesses both positively and negatively. Provide any personal examples from your experience
od pressure and hypertension via a community-wide intervention that targets the problem across the lifespan (i.e. includes all ages).
Develop a community-wide intervention to reduce elevated blood pressure and hypertension in the State of Alabama that in
in body of the report
Conclusions
References (8 References Minimum)
*** Words count = 2000 words.
*** In-Text Citations and References using Harvard style.
*** In Task section I’ve chose (Economic issues in overseas contracting)"
Electromagnetism
w or quality improvement; it was just all part of good nursing care. The goal for quality improvement is to monitor patient outcomes using statistics for comparison to standards of care for different diseases
e a 1 to 2 slide Microsoft PowerPoint presentation on the different models of case management. Include speaker notes... .....Describe three different models of case management.
visual representations of information. They can include numbers
SSAY
ame workbook for all 3 milestones. You do not need to download a new copy for Milestones 2 or 3. When you submit Milestone 3
pages):
Provide a description of an existing intervention in Canada
making the appropriate buying decisions in an ethical and professional manner.
Topic: Purchasing and Technology
You read about blockchain ledger technology. Now do some additional research out on the Internet and share your URL with the rest of the class
be aware of which features their competitors are opting to include so the product development teams can design similar or enhanced features to attract more of the market. The more unique
low (The Top Health Industry Trends to Watch in 2015) to assist you with this discussion.
https://youtu.be/fRym_jyuBc0
Next year the $2.8 trillion U.S. healthcare industry will finally begin to look and feel more like the rest of the business wo
evidence-based primary care curriculum. Throughout your nurse practitioner program
Vignette
Understanding Gender Fluidity
Providing Inclusive Quality Care
Affirming Clinical Encounters
Conclusion
References
Nurse Practitioner Knowledge
Mechanics
and word limit is unit as a guide only.
The assessment may be re-attempted on two further occasions (maximum three attempts in total). All assessments must be resubmitted 3 days within receiving your unsatisfactory grade. You must clearly indicate “Re-su
Trigonometry
Article writing
Other
5. June 29
After the components sending to the manufacturing house
1. In 1972 the Furman v. Georgia case resulted in a decision that would put action into motion. Furman was originally sentenced to death because of a murder he committed in Georgia but the court debated whether or not this was a violation of his 8th amend
One of the first conflicts that would need to be investigated would be whether the human service professional followed the responsibility to client ethical standard. While developing a relationship with client it is important to clarify that if danger or
Ethical behavior is a critical topic in the workplace because the impact of it can make or break a business
No matter which type of health care organization
With a direct sale
During the pandemic
Computers are being used to monitor the spread of outbreaks in different areas of the world and with this record
3. Furman v. Georgia is a U.S Supreme Court case that resolves around the Eighth Amendments ban on cruel and unsual punishment in death penalty cases. The Furman v. Georgia case was based on Furman being convicted of murder in Georgia. Furman was caught i
One major ethical conflict that may arise in my investigation is the Responsibility to Client in both Standard 3 and Standard 4 of the Ethical Standards for Human Service Professionals (2015). Making sure we do not disclose information without consent ev
4. Identify two examples of real world problems that you have observed in your personal
Summary & Evaluation: Reference & 188. Academic Search Ultimate
Ethics
We can mention at least one example of how the violation of ethical standards can be prevented. Many organizations promote ethical self-regulation by creating moral codes to help direct their business activities
*DDB is used for the first three years
For example
The inbound logistics for William Instrument refer to purchase components from various electronic firms. During the purchase process William need to consider the quality and price of the components. In this case
4. A U.S. Supreme Court case known as Furman v. Georgia (1972) is a landmark case that involved Eighth Amendment’s ban of unusual and cruel punishment in death penalty cases (Furman v. Georgia (1972)
With covid coming into place
In my opinion
with
Not necessarily all home buyers are the same! When you choose to work with we buy ugly houses Baltimore & nationwide USA
The ability to view ourselves from an unbiased perspective allows us to critically assess our personal strengths and weaknesses. This is an important step in the process of finding the right resources for our personal learning style. Ego and pride can be
· By Day 1 of this week
While you must form your answers to the questions below from our assigned reading material
CliftonLarsonAllen LLP (2013)
5 The family dynamic is awkward at first since the most outgoing and straight forward person in the family in Linda
Urien
The most important benefit of my statistical analysis would be the accuracy with which I interpret the data. The greatest obstacle
From a similar but larger point of view
4 In order to get the entire family to come back for another session I would suggest coming in on a day the restaurant is not open
When seeking to identify a patient’s health condition
After viewing the you tube videos on prayer
Your paper must be at least two pages in length (not counting the title and reference pages)
The word assimilate is negative to me. I believe everyone should learn about a country that they are going to live in. It doesnt mean that they have to believe that everything in America is better than where they came from. It means that they care enough
Data collection
Single Subject Chris is a social worker in a geriatric case management program located in a midsize Northeastern town. She has an MSW and is part of a team of case managers that likes to continuously improve on its practice. The team is currently using an
I would start off with Linda on repeating her options for the child and going over what she is feeling with each option. I would want to find out what she is afraid of. I would avoid asking her any “why” questions because I want her to be in the here an
Summarize the advantages and disadvantages of using an Internet site as means of collecting data for psychological research (Comp 2.1) 25.0\% Summarization of the advantages and disadvantages of using an Internet site as means of collecting data for psych
Identify the type of research used in a chosen study
Compose a 1
Optics
effect relationship becomes more difficult—as the researcher cannot enact total control of another person even in an experimental environment. Social workers serve clients in highly complex real-world environments. Clients often implement recommended inte
I think knowing more about you will allow you to be able to choose the right resources
Be 4 pages in length
soft MB-920 dumps review and documentation and high-quality listing pdf MB-920 braindumps also recommended and approved by Microsoft experts. The practical test
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One thing you will need to do in college is learn how to find and use references. References support your ideas. College-level work must be supported by research. You are expected to do that for this paper. You will research
Elaborate on any potential confounds or ethical concerns while participating in the psychological study 20.0\% Elaboration on any potential confounds or ethical concerns while participating in the psychological study is missing. Elaboration on any potenti
3 The first thing I would do in the family’s first session is develop a genogram of the family to get an idea of all the individuals who play a major role in Linda’s life. After establishing where each member is in relation to the family
A Health in All Policies approach
Note: The requirements outlined below correspond to the grading criteria in the scoring guide. At a minimum
Chen
Read Connecting Communities and Complexity: A Case Study in Creating the Conditions for Transformational Change
Read Reflections on Cultural Humility
Read A Basic Guide to ABCD Community Organizing
Use the bolded black section and sub-section titles below to organize your paper. For each section
Losinski forwarded the article on a priority basis to Mary Scott
Losinksi wanted details on use of the ED at CGH. He asked the administrative resident