5 Design Steps PDF

Summary

This document outlines the 5 steps in the engineering design process, focusing on identifying needs, evaluating alternatives, building and testing prototypes, and analyzing results. It also covers broader concepts in developing solutions to problems. This is written by helaly.

Full Transcript

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 Step 1.

Identify a need.

Needs (also called the problem you are
solving or the engineering goal) are
frequently identified by customers--the users
of the product.
The customer could be a retail consumer or
the next team in a product development.

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 Step 2.

Establish design criteria and constraints.

Design criteria are requirements you specify
that will be used to make decisions about
how to build and evaluate the product.
Criteria are derived from needs expressed by
customers.
Criteria define the product physical and
functional characteristics.
Some examples of criteria are shape, size,
weight, speed, ruggedness, and ease of
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 Step 3.

Evaluate alternative designs.

Your research into possible solutions will reveal what
has been done to satisfy similar needs.
You’ll discover where knowledge and science limit
your solutions, how previous solutions may be
improved, and what different approaches may meet
design objectives.
You should to consider at least two-to-three alternative
designs and consider using available technology,
modifying current designs, or inventing new solutions.

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 Development of Alternative Designs

❑ involves creativity and eng. tools
❑ CADD & computer modeling
❑ stress analysis
❑ material science
❑ manufacturing processes
❑ constraints must be identified & met
❑ availability of parts & materials
❑ personnel
❑ facilities

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 Step 4.

Build prototype of best design.
Use your alternatives analyses to choose the design that best
meets criteria considering the constraints, then build a
prototype.
A prototype is the “first full scale and usually functional form
of a new type or design” (Webster’s Dictionary).
Expense may limit full-scale; often prototype components
Prototype
1. An original model upon which something is patterned
(Webster)
2. A standard or typical example.
3. A first full scale and usually functional form of a new type
or design

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 Step 5.

Test and evaluate the prototype
(against important design criteria)

to show how well the product meets the need.
You should develop a test plan describing what you
will test, how you will test, and how you’ll perform
analyses. You must test your prototype under
actual or simulated operating conditions.
Customers are usually involved in product testing
so be sure you have an approval.

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 Step 6.

Analyze test results,
make design changes and retest.

Testing will disclose some deficiencies in your
design. Sometimes the testing fails completely
and sends the designer “back to the drawing
board.” Make corrections and retest OR
prepare an analysis of what went wrong and
how you will fix it. As always, document your
analyses, fixes, and retests in you project book.

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 Step 6.
Analyze test results, make design changes and retest.
Testing will disclose some deficiencies in your design.
Sometimes the testing fails completely and sends the
designer “back to the drawing board.” Make
corrections and retest OR prepare an analysis of what
went wrong and how you will fix it. As always,
document your analyses, fixes, and retests in you
project book.

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 Engineering
Design
Process
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 “The base of the design process is
creating a satisfactory solution to a need.”
The need may be to improve an existing
situation or to eliminate a problem. Or,
the need may be to develop a use for a
new discovery or concept.

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Engineering is all about—using knowledge and know-
how to achieve a desired outcome.
Designing is problem solving.
It is creative problem solving.
“Engineers are applications specialists”.
They apply the principles, discoveries, experiences,
techniques, and methods derived from ages of
research, experimentation, trial and error, and
invention

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 Design Requirements
Requirements are the necessary attributes defined for a system
before and during design.
The customer's need is the ultimate system requirement from which
all other requirements flow.
In addition, requirements are statements that identify the essential
needs of a system in order for it to have value and utility.
Requirements may be derived or based upon interpretation of other
stated requirements to assist in providing a common understanding
of the desired characteristics of a system.
Finally, requirements should state what the system is to
do, but they should not specify how the system is to do
it.

There are two types of system requirements:
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mandatory and14preference.
 Mandatory requirements:
❑(1) specify the necessary and sufficient conditions that
a minimal system must have in order to be acceptable
and are usually expressed with shall and must,
❑(2) are passed or failed (must not use scoring
functions), and
❑(3) must not be susceptible to trade-offs between
requirements.
❑After mandatory requirements have been identified,
Systems Engineers propose alternative candidate
designs, all of which satisfy the mandatory
requirements.
❑Preference requirements are then evaluated to
determine the "best" designs.
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 Preference requirements:
1) state conditions that would make the
customer happier and are often expressed
with should and want,
2) should use scoring functions to produce
figures of merit and
3) should be evaluated with a multicriteria
decision technique because none of the
feasible alternatives is likely to optimize all
the criteria, and there will be trade-offs
among these requirements.
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 Defining the Customer

The term customer includes anyone who has a
right to impose requirements on the system.
This includes end users, operators, bill payers,
owners, regulatory agencies, victims, sponsors,
etc.
Because Systems Engineering delivers both a
product and a process for manufacturing it, we
must also consider the customer of the process.

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 Stating the Problem
Stating the problem is one of the Systems
Engineer's most important tasks. The problem must
be stated in a clear, unambiguous manner.
State the problem in terms of what the world would be
like if the problem did not exist, and not in terms of
preconceived solutions

However, it is better to state the problem in terms of
the deficiency that must be ameliorated. This stimulates
consideration of more alternative designs.

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 Sources of Requirements
In this section we list two dozen sources of requirements.
However, Wymore (1993) says that only the first six
sources are necessary: Input-Output, Technology,
Performance, Cost, Trade-off, and System Test. He says all
of the other sources can be put into one of these six. Grady
(1993) says we should have only five sources: Functional,
Performance, Constraints, Verification, and Programmatic.
He thinks that most of our sources are constraints. The
EIA/ANSI-632 Standard on Systems Engineering says
there are only three: Functional, Performance, and
Constraints (Martin personal communication).

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 1-Input-Output
2-Technology
Perhaps the most
The technology requirement
common requirements
specifies the set of components --
relate the inputs of the
hardware, software, and bioware --
system to its outputs.
that is available to build the system.
For example, an input-
The technology requirement is
output requirement for
usually defined in terms of types of
an electronic amplifier
components that cannot be used,
that must be used, or both

3-Performance
Performance requirements include quantity (how many, how
much), quality (how well), coverage (how much area, how far),
timeliness (how responsive, how frequent), and readiness (ability,
MTBF).

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 4-Cost
There are many types of cost, such as manpower, resources, and
monetary cost. An example cost requirement would be that the
purchase price cannot be more than $10,000, and the total life
cycle cost cannot exceed $18,000.

5-Trade-off
Trade-off between performance and cost is defined as the
different relative value assigned to each factor. For example, the
performance figures of merit may have a weight of 0.6, and the
cost figures of merit may be given a weight of 0.4.

6-System Test
The purpose of the system test is to verify that the design and
the system satisfy the requirements. For example, in an
electronic amplifier, a 3-mV, 10-kHz sinusoid will be applied to
the input, and the ratio of output to input will be calculated.
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 7-Company Policy
Company policy is another way of stating requirements. For
example, Learjet Inc. has stated, "We will make the airframe, but
we will buy the jet engines and the electronic control systems."

8-Business Practices
Corporate business policies might require Work Breakdown
Structures, PERT Charts, Quality Manuals, Environmental Safety
and Health Plans, or a certain return on investment.

9-Systems Engineering
Systems or Software Engineering might require that every
portable disk (e.g., floppy or Bernoulli) have a Readme file that
describes the author, date, contents, software program, and
version (e.g., Word 6.0 or Excel 4.0).
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 10-Project Management
Access to source code for all software might be a project
management requirement. It takes time and money to install
new software. This investment would be squandered if the
supplier went bankrupt and the customer could no longer
update and maintain the system. Therefore, most customers
would like to have the source code. However, few software
houses are willing to provide source code, because it might
decrease their profits and complicate customer support

11-Marketing
The marketing department wants features that will delight
the customer. Kano calls them exciters. They are features
that customers did not know they wanted. In the 1970's, IBM
queried customers to discover their needs. No one
mentioned portability, so IBM did not make it a requirement

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 12-Manufacturing Processes
Sometimes we might require a certain manufacturing
process or environment. We might require our
semiconductor manufacturer to have a Class 10 clean room.
Someone might specify that Quality Function Deployment
(QFD) be used to help elicit customer desires (although this
would be in bad form because it states how not what).
Recently, minimization of the waste stream has become a
common requirement.

13-Design Engineers
Design engineers impose requirements on the system.
These are the "build to," "code to," and "buy to"
requirements for products and "how to execute"
requirements for processes.

14- Reliability
Reliability could be a performance requirement, or it could
be broken out separately.
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15- Safety
Some requirements may come from safety considerations. These
may state how the item should behave under both normal and
abnormal conditions.

16 The Environment
Concern for the environment will produce requirements, such as
forbidding the use of chlorofluorocarbons (CFCs) or
tetraethylchloride (TEC).

17- Ethics
Ethics could require physicians to obtain informed consent before
experimenting on human subjects.

18- Intangibles
Sometimes the desires of the customer will be hard to quantify,
such as for intangible items such as aesthetics, national or
company prestige (e.g., putting a man on the moon in the Apollo
project), or ulterior motives such as trying to get a foot in the door
using a new technology (e.g., the stealth
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business in a new country (e.g., China).
 19- Common Sense
Many requirements will not be stated because they are believed to
be common sense. For example, characteristics of the end user
are seldom stated. If we are designing a computer terminal, it
would not be stated that the end user would be a human with two
hands and ten fingers. Common sense also dictates that
computers not be damaged if they are stored at temperatures as
high as 140°F. Furthermore, we do not write that there can be no
exposed high voltage conductors on a personal computer, but it
certainly is a requirement. Many of these requirements can be
found in de facto standards.

20- Laws or Standards
Requirements could specify compliance with certain laws or
standards, such as the National Electrical Code, City/County
Building codes, ISO-9000, or the IEEE 1220 Standard for Systems
Engineering.
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21- The Customer
Some requirements are said to have come from the customer,
such as statements of fact and assumptions that define the
expectations of the system in terms of mission or objectives,
environment, constraints, and measures of effectiveness. These
requirements are defined from a validated needs statement
(Customer's Mission Statement), from acquisition and program
decision documentation, and from mission analyses.

22- Legacy Requirements
Sometimes the customer has definite requirements that are not
stated. For example, "Your last system was robust enough to
survive a long trip on a dirt road, so we expect your new system
to do the same."

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 23- Data Collection Activities
If an existing system is similar to the proposed new system,
then existing data collection activities can be used to help
discover system requirements, because each piece of data that
is collected should be traceable to a specific system
requirement. Often it is difficult to make a measurement to verify
a requirement. It might be impossible to meet the stated
accuracy. Trying to make a measurement to verify a requirement
might reveal more system requirements.

24- Other Sources
There are many other sources of system requirements, such as:
human factors, the environment (e.g., temperature, humidity,
shock, vibration, etc.), the end user, the operator, potential
victims, management, company vision, future expansion,
schedule, logistics, politics, public opinion, business partners,
past failures, competitive intelligence, liability, religion, culture,
government agencies (e.g., DoE, DoD, OSHA,
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 Testing and Evaluation
Step 5.
Test and evaluate the prototype against important
design criteria to show how well the product meets the
need. You should develop a test plan describing what
you will test, how you will test, and how you’ll perform
analyses. You must test your prototype under actual or
simulated operating conditions.

Evaluation of designs/Selection of optimal design
One or more of the designs must be fabricated
Thorough testing must be done to ensure the product
meets performance specifications
Based on the results of the testing, the design is
finalized
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 This is where the rubber meets the road! Remember those
specifications you developed back at the beginning of the
project? It's time to pull those out again and test your
product to make sure it meets every single spec! Make
sure you test it thoroughly before you release it to the
customer.

Four things can happen at this point:
1.The product doesn't meet the spec
2.The product meets the spec but the spec was wrong
3.The customer changed his/her mind
4.The product meets the spec and the customer is happy

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 A critical element of the requirements
development process is describing the tests,
analysis or data that will be used to prove
compliance of the final system with its
requirements. Each test must explicitly link to a
specific requirement; this will help expose
untestable requirements. Describing the system
tests informs the producers how the system will
be tested, so that they know how they will be
"graded."

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 This process frequently uncovers overlooked
requirements.
At this time it may be useful to examine the
following definitions.

Validating a System:
Building the right system; making sure that the
system does what it is supposed to do. It
determines the correctness of an end product,
compliance of the system with the customer's
needs, and completeness of the system.

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 Validating Requirements:
Ensuring that the set of requirements is
consistent, that a real-world solution can be
built that satisfies the requirements, and that
it can be proven that such a system satisfies
its requirements.
If Systems Engineering discovers that the
customer has requested a perpetual-motion
machine, the project should be stopped.

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Verifying a System:
Building the system right; ensuring that the system
complies with its requirements. Verifying a system
determines the conformance of the system to its
design requirements. It also guarantees the
consistency of the product at the end of each
phase, with itself and with the previous prototypes.
In other words, it guarantees the honest and
smooth transition from model to prototype to
preproduction unit. to production unit.

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 Verifying Requirements:
Examination, analysis, test, or demonstration that
proves whether a requirement has been satisfied.
This process is iterative. The requirements should be
verified with respect to the model, the prototype, the
preproduction unit, and the production unit.
For Systems Engineers, to validate requirements is to
prove that it is possible to satisfy them. System
verification, on the other hand, is a process of proving
that a system meets its requirements.
To add further confusion, ISO-9000 tells you to verify that
a design meets the requirements and validate that the
product meets requirements.

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 Prototyping
A good design isn't worth anything unless you can
actually make something. The goal of prototyping is
to follow the recipe that you developed during
detailed design and actually build a product. If you
did a good job and accurately documented the
design, prototyping is simply a matter of following
the directions. If you find yourself continuing to
work out the details of the solution, then you need
to go back to detailed design and make corrections.
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 Prototypes can serve three different purposes.

One purpose is that of function, the ability of a proposed
design to operate in a desired way. In the mechanical
world, this is often known as a working prototype, and
demonstrates that the essential functionality of a design
operates as intended.
A look-and-feel prototype is used to understand what the
form and appearance of a design should be. An example is
a non-functional industrial design model made of foam or
rendered in 3-D.
Finally, role prototypes give a sense of the usability of a
design. Storyboards are often used to illustrate how and
under what contexts a product might be employed by an
end user.
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