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Frances Alston, PhD, CHMM, CPEM Director, Environment Safety & Health
Lawrence Livermore National Laboratory
Dr. Alston has built a solid foundation of more than 25 years where she has led the development, management, and implementation of Environment, Safety, Health and Quality (ESH&Q) programs. In these leadership and program management roles, she has worked with a wide array of regulatory agencies and organizations, stakeholders, and communities. Her experience also encompasses international collaboration where she designed and championed implementation of an occupational hygiene program based upon European Health and Safety Standards for use in the United Kingdom.
She has a Ph.D. in industrial and system engineering and a MSE degree in engineering management, both from the University of Alabama. She earned a master’s degree in hazardous and waste materials management/environmental engineering from Southern Methodist University and a bachelor's degree in industrial hygiene and safety/chemistry from Saint Augustine's College.
Dr. Alston is the President and a Fellow of the American Society for Engineering Management (ASEM). She holds certifications as a Certified Hazardous Materials Manager (CHMM) and a Certified Professional in Engineering Management (CPEM). Dr. Alston is the author of Culture and Trust in Technology-Driven Organizations, Lean Implementation: Applications and Hidden Costs, and co-author of Guide to Environment Safety & Health Management and Industrial Hygiene: Improving Worker Health Through An Operational Risk Approach.
About the Past Presidents of the Society Award
This annual award is given to the individual who served as President of ASEM during the past year. At the International Annual Conference during the “passing of the gavel,” a plaque is awarded to the outgoing president.
More information about the award is available here:
Past Presidents Of The Society Award
A list of past recipients is available here:
List of Past Recipients
NOTE: ASEM wants to recognize all 2018 award winners. If you received an award and did not provide your biographical information, you still can. Please help us by completing this short Google form at https://goo.gl/WULsGW - thank you!
(EMBOK Blog Post #9)
Dictionary.com defines innovation as “something new or different introduced.” Engineers of all stripes are involved daily in creating and introducing new and different processes and products. We work in the creation of new knowledge that pushes the boundaries of scientific understanding. And we work to improve the efficiency and productivity of manufacturing systems to deliver products and services to a global customer base. At the heart of innovation is providing “new and different” to customers.
Domain 8, “Management of Technology, Research, and Development,” in the Engineering Management Body of Knowledge (EMBOK) complements Domain 7, “Marketing and Sales Management in Engineering Operations” because only innovations that support market needs are desired. Domain 8 also directly ties to Domain 4 and Domain 5 which discuss financial management and project management, respectively. Finally, Domain 3, addressing strategic planning, is a key input to any innovation process. (Get your copy of the EMBOK here.)
Innovation is comprised of several areas of technical expertise and of engineering management practice. Innovation starts with the organization’s strategy to provide a mission for R&D teams, developers, and design engineers. As described in Sections 8.2 and 8.3 of the EMBOK, companies are striving for higher levels of innovation to deliver product and process improvements faster due to pressures from globalization and rapid technology advances. Industries are being disrupted by low-cost competitors as well as alternative products and services that previously didn’t exist.
Consider that today we call an Uber or Lyft ride from our cell phone and pay a negotiated rate, when just a few years ago, we instead queued up at taxi stands and paid a rate fixed by the local government rather than a rate fixed by the local government rather than a free market rate.
Engineers and engineering managers are involved at all stages of innovation and technology management and may find themselves working in different arenas at different points in their careers. For example, a newly minted engineer may work on process improvements in the plant or factory as a contact engineer. Innovation assignments at this stage involve improving process throughput and reducing defects and downtime to improve the product quality. (Please also see the post on Domain 6, “Quality, Operations, and Supply Chain Management.”)
Next, an engineer may work on the design and development of a new product or process. New products are typically created following a standard project management process and follow stages as described in Section 8.5.
An important element to successful new product development (NPD) is to consider life-cycle design, including “D4X” or “design for ____”. Successful innovations address D4X upfront, such as Design for Environment (Section 18.104.22.168) and Design for Reliability (Section 22.214.171.124). Attention to such details improves the acceptance of the new product or process by both internal and external customers.
Engineers and engineering managers may also spend time working in R&D labs. As described in Section 8.1.1 of the EMBOK, R&D activities range from scientific discovery to applied technical research, and to design and development functions described above. In research labs, engineers and engineering managers work closely with specialists, such as chemists, physicists, and material scientists, to convert conceptual ideas into practical manifestations. R&D engineers often bridge the gap between fundamental science and functional implementations. After all, most inventions are not profitable until they are translated to innovative products which are manufactured and sold into a marketplace.
Finally, at advanced career stages, engineering managers help to direct and frame the R&D and innovation programs to meet strategic goals of the organization. Some innovation strategies will involve projects to address weaknesses and threats to the company or industry by global competition or from new technologies. Other R&D projects will capitalize on the strengths and opportunities of an individual company that has discovered new technical applications to improve existing products or operations. Engineering managers will also work closely with other corporate executives to select the most appropriate portfolio of innovation projects to advance the organization’s strategic vision.
Innovation is a tremendously exciting field in which engineers and engineering managers are privileged to work. Domain 8 of the EMBOK provides a tiny taste of the wonderful and vast career opportunities in new product development and R&D. As you read through Domain 8, you will note that innovation touches and is touched by virtually every other domain in the EMBOK. Engineers and engineering managers create and improve products and processes deploying a wide range and depth of skills and competencies. And while every day is different and technically challenging, engineers and engineering managers that support innovation activities are never bored!
Please feel free to contact me for more information on innovation – it is my passion and I feel lucky to share this brief overview of EMBOK Domain 8, “Management of Technology, Research, and Development”.
Today, consider how your work as an engineer or engineering manager impacts innovation. What can you do to improve technology in processes or products?
Teresa Jurgens-Kowal, PE, CPEM, PMP®, NPDP, is a passionate lifelong learner. She enjoys helping individuals and companies improve their innovation programs and loves scrapbooking. You can learn more about Teresa and her new Innovation MasterMind group by connecting on LinkedIn.
By Patrick Sweet, P.Eng., MBA
(Blog #8 EMBOK series)
Photo credit: https://stocksnap.io/author/rawpixel
In this month’s installment on The Business-Savvy Engineer, I tackle Domain 7 of the Engineering Management Body of Knowledge (EMBoK): Marketing and Sales Management in Engineering Organizations.
For many, marketing and sales seems like it would be far outside the scope of what an engineer would care about – even an engineering manager. However, that’s not really the case. Engineers everywhere are involved in activities traditionally reserved for marketing and sales people. Figuring out how to meet a customer’s needs, helping convince a prospective customer to choose a product or service, and developing spec sheets for a conference are all marketing and sales activities that engineers are routinely involved in.
When you consider the link between engineers, customers, and the development of winning products, it’s easy to see how knowledge of marketing and sales could be of significant benefit to engineering managers.
The rest of this post will touch on some of the most important elements from Domain 7 in the EMBoK.
Sales is the act of motivating a potential customer to make a decision to purchase a product or service. Advertising is communicating to a target audience in an effort to make that audience aware of products and services that exist. Both advertising and sales are critical to helping get the products and services that engineers create into the hands of the right people.
It’s important to understand that, when advertising and selling internationally, differences in culture and language need to be taken into account in order to be successful. One example of this was shared by Blackberry co-founder, Mike Lazaridis, at an engineering conference I went to while in engineering school. He shared with the audience that they had hired a marketing firm to help them come up with the name “Blackberry” to ensure it translated well in several languages and wouldn’t be awkward in other cultures. The name Blackberry was the last of over 100 names that the company had come up with. Contrast this with the Chevy “Nova”, which roughly translated to the Chevy “No Go” in Latin American markets.
Customer satisfaction is important for any organization to measure and manage. Engineering managers are not exempt from this. Customers are well-informed, intelligent, and able to chose different providers if they aren’t satisfied with your products or services. This counts as much for internal customers as it does for external customers. I’ve experienced situations where my company paid external service providers to do work that an internal division were capable of because the internal division was too difficult to deal with. This is a clear example of poor customer satisfaction.
In order to improve customer satisfaction, it must first be measured. Traditional techniques for measuring customer satisfaction include surveys, focus groups, and interviews (see ASEM’s current membership survey here). It is very important to design these tools carefully, as poor design can obfuscate results, and even lead to drawing incorrect conclusions. Managers may consider hiring outside experts for launching new customer satisfaction initiatives.
Marketing is the act of determining what a given market needs and how to satisfy that need given what the organization’s capabilities are and what competitors are doing. Marketing involves four primary elements, commonly known as the “Four Ps” of marketing:
Engineers play a key role in developing an organization’s products and services, establishing cost structures (which informs price), setting up distribution channels, and developing product specifications and trade show materials.
Branding is about giving products an identity that acts as shorthand for the attributes of a given product. BMW’s brand stands for luxury and performance. Walmart’s brand stands for value and convenience. Both brands say very different things, but are equally powerful. Engineers play an important role in giving brands credibility through their design decisions.
Products progress through lifecycles. After a product is launched, it will process through a period of growth, reach maturity, hit market saturation, and eventually decline. It is important for organizations to have an array of products at various phases in their lifecycles so that the risk of a product falling out of favour in the market and leaving the company stranded is reduced.
Another important way to look at products is through the “Boston Matrix”, which plots products on a chart with relative market share on one axis and industry sales growth rate on the other. The matrix can be split up into four categories, as shown in the table below:
Relative Market Share Position
Industry Growth Rate
Understanding where products fall on the Boston Matrix can help organizations understand what to do with each product in their portfolio and where to invest product development dollars.
With globalization, companies in every industry will be faced with at least one of the following: competition from abroad, needing to source materials or talent from abroad, or trying to enter overseas markets. As was discussed in the section on advertising in foreign markets, it is important to bear in mind that values and management practices differ throughout the world. Managers cannot assume that business as usual will work in any other market.
Given that operating in markets outside your home can necessitate different practices, it is important to be aware of the various options that are available for doing business abroad. Domestic companies can import or export goods, invest directly in foreign entities, license their products or services to others, set up franchises, or use management contracts to profit from outside markets.
A product’s price is what the customer pays for a given product. Pricing is something of an art and must take into account the customer’s ability to pay, the organization’s goals and targets, the product’s cost, and how the competition prices alternative products. Pricing should not be driven by cost alone and needs to reflect the value conferred by the product. For example, books generally cost pennies to produce, but are priced orders of magnitude higher. This is because they provide much more value than the sum of their physical parts.
Engineers can be heavily involved in product pricing, especially with respect to controlling product costs and understanding how competitors’ products are positioned.
At first glance, this domain may seem out of place in an engineering management book. In reality, marketing and sales management is tightly coupled with engineering and engineering management. An understanding of the business side of product development, marketing, advertising and sales on the part of engineering managers can be of enormous benefit to both managers and the companies that employ them.
Patrick Sweet, P.Eng., MBA, ASEP is a recognized expert in engineering management and leadership with expertise in systems engineering, project management and product management. You can read more from Pat at the Engineering & Leadership blog.
Most of us have great ideas that we think could turn into great businesses. Just the other day, for instance, I told the blood donation attendant about my great idea to have a manicurist perform her magic during the procedure. Of course, there are some obvious holes in my “great idea”.
Yet, other people can convert ideas into business success. How do they do this and is there a formula for entrepreneurs?
Amy Wilkinson, author of “The Creator’s Code,” says, “YES!” And she shows us six essential skills in her book. The text is based on interviews with over 200 entrepreneurs who started companies that generate greater than $100M in revenue each year (pg. 9). These include companies like Under Armour, Airbnb, Dropbox, Chipotle, and JetBlue.
The first step is to identify an opportunity that others don’t see. Sounds easier said than done, but the author explains that some people are able to transport solutions from one industry to another. For example, Howard Schultz didn’t invent the idea of a coffee bar. Instead, he saw a unique culture in Italy and transported the community of coffee into the Starbuck’s business model.
Next, successful entrepreneurs seek the future over the past. Wilkinson calls this “to-go” thinking over “to-date” thinking. Research shows that considering what you have left to do to complete a task enhances motivation (pg. 58-59). Retrospective thinking can make us lazy.
The third skill in “The Creator’s Code” is to “fly the OODA loop” (Chapter 3). The acronym OODA comes from a Korean War era Air Force pilot: observe, orient, decide, and act. Success entrepreneurs gather a lot of data (observe), interpret the data (orient), make quick choices (decide), and then implement a plan (act). Feedback from markets, customers, and experiments go back into the cycle as observations to continue learning.
Chapter 4, “Fail Wisely,” describes the next skill in the “The Creator’s Code.” Creators share one trait: failure (pg. 101). Of course, failure doesn’t feel good, but it does provide learning. Successful entrepreneurs are okay with making low-risk mistakes and are self-aware enough to ask for help when necessary. Creators utilize a “growth mindset” (pg. 128-130, see also the book review on Mindset.)
Next, successful entrepreneurs use opportunity identification and learning from failure to build cognitive diversity. Wilkinson calls this “networking minds” (Chapter 5). As design thinking teaches us, we cannot solve problems in isolation. Collaboration and feedback help us to generate the best solutions (pg. 141).
Finally, the sixth element of “The Creator’s Code” is to “Gift Small Goods” (Chapter 6). In short, the author explains that collaboration, networking, and doing favors for others pays back. The author relays the Christmas card study by Phillip Kunz at BYU. He hand-signed 600 cards and sent them to absolute strangers. He received over 100 return greetings, complete with well wishes for his family, photos of kids and pets, and hand-written message. People appreciate acts of kindness and will repay them.
So, the six elements of becoming a successful creator and entrepreneur are more about behaviors than technical skills. Wilkinson teaches us that we need to identify unsatisfied customer needs, to try and try again, learn from failure, and collaborate with others. How do we apply these skills as engineering managers inside corporations instead of acting as solo entrepreneurs?
I believe “The Creator’s Code” gives engineering managers tools to enhance and empower teams. Corporate product and project management also depends on finding gaps in markets and technologies that match the core competencies of the firm. Success as engineering managers also requires us to “fly the OODA loop,” to fail wisely, and to network minds. Recognizing the strength of those around us and building an entrepreneurial environment can also build success for our engineering and project teams.
I recommend “The Creator’s Code” for engineering and engineering manager who are curious about curiosity and want to understand the traits of successful creators. The stories that Wilkinson presents are intriguing. It’s a quick and easy read – maybe a book suitable for scanning while you lay on the beach this summer!
What skill can you transport from the entrepreneurial world to make your engineering project teams more successful?
It has been a beef of mine that many management studies look at successful companies and try to figure out best practice based on what these top performers do. If you hear that (hypothetically) 75% of successful companies have a matrix organization and 25% have a hierarchical structure, you may think a matrix is for you. However, it is difficult to get a lot of data on the companies that struggle whereas they like to advertise success. With my example, if you hear that 95% of the poor performers have a matrix versus 5% hierarchical, that provides a different picture.
I like that the authors of Six Batteries of Change have extensive experience consulting on change management programs. Geert Letens is familiar to many readers as a former president of the American Society of Engineering Management and I like his practical and critical perspective of EM principles. This book is based on data collected from participants at 111 companies. Two people at the same company can have differing opinions on its performance and culture that makes you wonder if they are confused about where they work. This book recognizes this and therefore multiple sources at each organization were used. They also recognize the different perspectives (or realities) of workers on the floor versus the planners in the “ivory tower.” By having these multiple inputs and a diverse range of sizes and business types they draw from, we are presented with a nice spectrum of traits of those that are successful and those that struggle with transforming their business.
During my career, six particular companies stand out that would have benefited from this book. All six could see that they needed to change or fail. Three talked about “burning platforms” but continued on their downward trajectory and closed shop. The other three initiated formal cultural change programs but these fizzled out prior to them closing for business. Unlike much of the literature I have read, this book generally agrees with my views on organizational culture and change.
I was in a meeting recently with directors who were reviewing a new program. As mentioned in this book, executives are busy and do not want to be bombarded with too many concepts. The key to getting buy-in is to have a few fairly simple points and to repeat them in a variety of ways, driving home the message. For implementing change successfully, the authors developed a concept of relating behavioral characteristics to energy levels in a battery. These are put in a grid with one axis for the often competing motivations in people: the emotional and the rational. The other axis separates the strategic policies needed to create proper alignment from the operational procedures to assure solid execution at the ground level. As was recognized at least as far back as the Hawthorne Experiments of the late 1920s, good ideas can fail if improperly implemented and yet irrational, counterintuitive plans can have positive results if rolled out in the right way to appeal to the workers. Hence, we are presented with a framework of six categories of batteries (or energy levels) that will lead you to greater chance of success when these batteries are properly topped up. The book provides examples of both good and poorly charged batteries in companies familiar to many readers, such as Yahoo, Nokia and ING. It provides symptoms of good and poor cultures and steps for charging the batteries in areas that are low, establishing an architecture for positive change.
I started out by reading Chapter 9 first as check for the book’s usefulness as a quick reference or as a refresher. I was able to follow the concepts easily without having to rely upon any complicated or specialized vocabulary built in the earlier chapters. I liked that there was a definite lack of prescriptions for success, since the authors recognize that organizations are now in a world that is VUCA - volatile, uncertain, complex, and ambiguous. They also recognize that change is not achievable through the actions of a small group and it must be driven throughout the organization. I have painfully watched my former employers bring on a small group of experts tasked with somehow fixing the organization’s ills under a two-month contract, which goes a long way to explaining why they are former employers.
Many people who will read this will be somehow connected to a cultural transition program within their organization. Using this book to help guide the process will be a smart move.
Dr. Kennedy has been a regular attendee of the ASEM conference since 1999, with particularly good participation at the informal late evening "discussions" (sometimes making it difficult to get to the morning plenaries). He has spent much of his time working on large construction projects in remote areas, lecturing at a few universities, and is now trying his hand in an unfamiliar role as a director of engineering in R&D.
The next day Trish and I visited ASEM member Rod Grubb at the 4M headquarters http://4mio.com/. Rod played a number of valuable roles with ASEM in the past and we wanted to drop in on him while we were in Knoxville. During the tour of the facilities, Rod was clearly proud in the success of his company and the fascinating developments in the future for carbon fiber. Afterwards, we were introduced to Rob Klawonn and Mike Agentis who were also excited about the advances. Each conversation circled back to engineering management and networking.
Over the two-day visit, Dr. Conner and Rita Gray coordinated visits for us on the beautiful campus of the University of Tennessee. We visited with Dr. Eric Boder, Dr. Gabriel Goenaga and Dr. John Kobza to discuss the value of ASEM to their students as they [the students] move into a future management role. With many students attending through distance courses, a conversation in developing a virtual student chapter was a focus. Dr. James Simonton also helped to develop a vision statement to guide the next steps. It will be exciting to see the University of Tennessee as part of the ASEM family.
Dr. Harold Conner was instrumental in putting all the parts together to make the trip a success. It was evident by our conversations that Dr. Conner has strong beliefs in engineering management and he appreciates the role that networking plays throughout the career of an engineering manager. This was demonstrated through his connections with multiple professional societies and with the University of Tennessee. ASEM thanks Dr. Conner for his support as a sponsor. It’s great to see Dr. Conner continue his support by bringing a student to the ASEM IAC to experience conferences and to build their network. This year, Dr. Conner is bringing Jake Beatty (bio below).
About Jake Beatty
Jake Beatty, from Clarksville, Tenn., is in his senior year as an industrial engineering major at the University of Tennessee-Knoxville (UT). He is also working toward a minor in reliability and maintainability. He served a 2018 summer internship at URS | CH2M Oak Ridge LLC (UCOR) supporting UCOR’s LEAN program. That support included working to consolidate eight different waste software programs into one. Jake is a member of the Knoxville Chapter of Institute of Industrial and Systems Engineers and has participated in 20 hours of volunteer work each semester at UT.
This summer, ASEM took promoting the society to a new level. We welcome new members from the Minneapolis (ASCE-EWRI) and Evanston (IEEE-TEMS) conferences. We are looking to expand our presence at more conferences through the New Year. I’ll share more plans in upcoming eNews articles. I’m also looking for networking stories to share with our society. If you have a similar story to share about mentoring success or professional networking, please send it to email@example.com
(EMBOK Blog Post #7)
I am currently in the market for a new car. One of the first characteristics that I can list is that I want the vehicle to be of high quality. But, what, exactly, does “quality” mean? Domain 6 of the Engineering Management Body of Knowledge (EMBOK, 4th edition) teaches us about quality as well as operations and supply chain management.
As noted in the EMBOK (pg. 165), quality is “defined for each product based on what the customer wants in … measurable characteristics.” Certainly, this definition helps as I want my car to have at least 200 hp, not cost over $40,000, and be reliable for a lifetime of ten years. Rather than getting a sales pitch from a car dealer, they can instead show me new models that have specifications matching my desired quality characteristics.
The foundations of quality management in US, Canadian, and Western European industries started with the automotive industry. But, the principles of quality date further back to WWII when General Douglas MacArthur sought good radios in Japan. Influential quality gurus like W. Edwards Deming, Joseph Juran, Phillip Crosby, and Kaoru Ishikawa not only helped MacArthur in his quest for good radios, but also spawned the total quality movement. The Toyota Production System (TPS) is known for yielding high quality, low variability parts and a novel approach to manufacturing (which we now call “lean”).
The quality gurus shared a common belief that management must actively participate in quality improvement and that systems and data drive performance improvements. Ishikawa delineated a list of data-driven tools for engineers and managers to improve quality. These are shown in Table 6‑4 of the EMBOK (pg. 168) and include the affinity diagram and the prioritization matrix. R&D engineers will be familiar with these tools as project managers are also intimately familiar with the activity network diagram.
Quality in organizations today is supported by international standards, such as ISO 9001 and ANSI. In the US, the Malcolm-Baldrige Award is presented by the President to organizations that have demonstrated commitment and improvement through total quality management (TQM).
Of course, quality is more than a measure of the final product. Process improvements to drive and support quality are a key task for engineers and engineering managers. Systems like lean manufacturing and Six Sigma encourage continuous improvement by eliminating waste and minimizing variation. Section 6.2 of the EMBOK compares and contrasts the principles of lean with Six Sigma improvement projects.
An important concept in lean is “flow,” especially for batch operations. Tools in lean help to reduce wasted time as a machine or downstream customer waits for work. The Kanban board is a visual tracking tool to show planned work, work-in-progress, products undergoing testing, and complete work. New work does not enter the “flow” until the Kanban board shows capacity of the work team to accept new work.
Like lean, Six Sigma is also driving a goal of continuous improvement. Six Sigma is project-oriented to find the root cause of a quality issue and implement an improvement. The core philosophy of Six Sigma is the DMAIC cycle, which includes the following steps:
Of course, quality and operations management are not standalone functions. Operations must support product manufacturing and involves creating sales forecasts and inventory management. For example, production of one new car (Volvo XC40) is unable to meet customer demand because of underestimated sales forecasts, resulting in a waiting period to even test-drive the vehicle and an even longer waiting period for purchase. Engineering managers use a variety of forecasting, scheduling, and inventory management tools to avoid these situations. (Supply chain management is discussed in detail in Section 6.6 of the EMBOK).
While not all engineers and engineering managers work directly in quality assurance (QA) or quality control (QC) labs or even in operations or supply chain, each of us must be fully committed to quality management. As Domain 6 of the EMBOK points out, engineering managers influence and impact quality from the concepts of new product development through ongoing continuous improvement activities. We must remember at all times that it is our customer and our customer’s customer who define quality.
Oh yeah, and I want a blue car…
What activities are you doing today in your job as an engineer or engineering manger to improve quality in your organization?
Get your copy of the EMBOK here. There are also many great tools on economics and finance in the EM Handbook here. Past articles in this series include:
The Western Michigan University (WMU) student chapter of ASEM consistently improves, and is growing from years past. Students participated in school activities, the ASEM IAC, industry tours, and fundraisers. With the focus being to encourage EM development, here are report summaries for each event:
Bronco Bash: This is an event that takes place first week of September each year and 150+ RSOs have a booth to get people interested in joining an RSO. This is a fun way for RSOs to interact with students new to the university. This was the second time that the WMU chapter of ASEM took part in this and it was great talking to freshmen about what ASEM is and what our major is.
ASEM Conference: The annual conference in Alabama was a great experience for those that went to it. We got a chance to interact with professionals from industry working the job what we might have one day. We were able to get nine students to the conference through the use of a fund set aside for ASEM by our Advisor, Dr. David Lyth, and through the funding from our Dean, Dr. Houssam Toutanji.
JR Automation: Our first tour was to JR Automation, manufacturer of custom automation equipment, which included talking to the management team there and a tour of their plant.
Green Door Distilling Co: This was our second tour and a unique one. This is a distilling company was founded by an alumnus from the WMU Engineering Management master’s program. The tour showed our students in the program how Jon, founder of Green Door, was able to apply all that he learn from school and start his own company.
Bells Brewery: The third tour we took was to Bells Brewery right here in our back yard. We were able to see the entire process of how their products are made, from grains to the bottling line. We were also able to taste their product.
Stryker: Our last tour was at Stryker Instruments and for this tour we are planning to see operations that take place there. The tour was set up through an alumnus from the engineering management technology program at WMU that works at Stryker. This tour gave us insights on how a Fortune 500 company carries out its operations.
Blaze Pizza: This was our first fundraiser of the semester and we got in contact with Blaze Pizza for setting up this fundraiser. It was delicious! We may potentially do it again in the future.
Cookie Sale: For our second fundraiser we got a donation of cookies and we baked them and had a bake sale. This was something new that we tried whereas in the past we had contacted a local business and had a fundraiser there. This was an idea that would be good to use again in the future.
This year, the WMU ASEM Student Chapter will continue to connect students to industries where they might work. The plan is to reach out to the underclass students and have them get involved. Participating in the Bronco Bash provides good exposure for the chapter. Along with that, students will be presenting papers at the ASEM conference, and a case study team is currently being organized. After the IAC, students hope to participate in an improvement project with YWCA in Kalamazoo. Lastly, the students strive to partner with other engineering RSOs both in fundraising, and activities.
ASEM Members, please submit your nominations for the many prestigious ASEM awards, by visiting https://goo.gl/forms/3BqwM6IWjycUNJL33 before July 15, 2018. The awards are:
Bernard R. Sarchet Award: Considered to be the highest award given by ASEM. This award recognizes contributions to the Society and to the field of engineering management and is annually given to an ASEM member who has contributed the most to the Society on a local, national and/or international basis.
Frank Woodbury Special Service Award: Recognizes an ASEM member who has provided outstanding service to the Society. This award is given annually to an active ASEM member who has demonstrated proof of continued service excellence to ASEM.
Meritorious Service Awards: Recognizes the effort of the local sections of ASEM. Awards include:
Presidential Award – Local Section: Annually recognizes ASEM local section excellence. All active ASEM local sections are eligible. Criteria for this award include:
Best Dissertation Award: Annually recognizes the PhD dissertation that makes the most significant contribution to the engineering management field. Visit http://asem.org/resources/Website/About/Society%20Awards/2018%20-%20ASEM%20%20BDA%20-%20Call%20for%20Nominations%20-%207%20April%202018.pdf for complete instructions
William Daughton World Headquarters Service Award: Recognizes significant contributions to the streamlining, enhancement, or improvement of the day-to-day operations of ASEM world headquarters.This award recognizes an active ASEM member for their contribution of time, effort, or implemented idea that significantly enhanced or improved the day-to-day operation of ASEM including but not limited to:
For more information about this award, and all of ASEM's Society Awards, please visit: https://asem.org/Society-Awards or contact firstname.lastname@example.org.
By Patrick Sweet, P.Eng., MBA
(Blog #6 EMBOK series)
Photo credit: Thijs van der Weide
The vast majority of engineering work takes place in the form of projects. A project is a one-time, temporary endeavor aimed at creating a unique product, service, or outcome. Many engineers turn to project management at some point in their careers. Others, while they may not be interested in leading projects, will almost certainly work in a project environment.
Chapter 5 in the Engineering Management Body of Knowledge (EMBoK) covers the basics of project management. This post will summarize the most important points of the chapter in the hopes that it will serve as a useful primer and encourage you to dig into the EMBoK if you’re interested. You can order your copy of the EMBoK here.
Project management is the art and science of initiating, planning, executing, controlling, and closing projects. When an organization recognizes some sort of need or opportunity, a project is typically launched to address or pursue it. It is the project manager’s job to define the work, organize the required resources, and see to it that the need or opportunity is addressed on time, on budget, and with the right quality. In many ways the project manager is like the CEO of the project – they hold the ultimate responsibility.
Initiation is a crucial step in running a successful project. When initiating a project, the project team determines what exactly the project is meant to do, and how it will affect the project’s stakeholders. Stakeholders are anyone who can be directly or indirectly affected by the project, or who could affect the project. For example, for a hydroelectric dam construction project, the local electric utility, local government, and conservationists could all be pertinent stakeholders, each with very different views to take into account. Understanding the people involved and the ultimate goal of the project is critical before moving forward.
Project planning is a major effort in the early stages of the project. When planning, the project manager determines what work will be done and what won’t be done. This is called the project’s scope. The project manager will also organize the scope into a work breakdown structure to organize everything that needs to be done and to facilitate scheduling the work and assigning it to the right people. At the end of the planning effort, the project manager should have a plan for the work that will be done, how much it costs, and how long it will take.
Risk is the effect of uncertainty on a project’s goals. There can be both positive and negative risks, often called opportunities and threats, respectively. Risks can be categorized according to their likelihood of occurrence and the level of impact that they would have if they were to occur. A highly likely, highly problematic threat requires a mitigation plan from the project manager. Risks can be managed through four typical strategies: acceptance, avoidance, transference, or mitigation. Similarly, opportunities can be pursued as well, which is an important way to help mitigate the effects of risk on a project.
Project work actually occurs through project execution. This is a very important phase of a project because this is typically where the majority of money is spent on a project. If a project manager isn’t careful, money can be spent doing the wrong work, or doing poor quality work. Both result in delays and overspending which threaten the success of a project. The project manager must be skilled at building and leading high-performing teams in order to succeed in project execution.
In order to make sense of how a project is proceeding, a project manager will monitor the project in several ways. Using earned value methodology, the project manager will look at what has been accomplished, how much money has been spent, and what was expected to be accomplished and spent based on the original plan. Using these metrics, it is possible to determine if the project is on schedule and on budget. If the measurements show a significant deviation, then the project manager must take action to correct the issue.
At the end of a project, the effort must be formally closed. For successful projects, that means securing acceptance and payment for the project’s deliverables. The project manager should also host a post-mortem with the project team in order to elicit lessons learned for use on other projects in the organization. This will facilitate better project planning and execution in the future and elsewhere in the organization.
Projects are a ubiquitous part of an engineer’s day-to-day life. You will, in all likelihood, find yourself leading or participating in a project team at some point in your career. Understanding the basics of project management can make all the difference in the world when it comes to project success, no matter what your role is.
Patrick Sweet, P.Eng., MBA is a recognized expert in engineering management and leadership with expertise in systems engineering, project management and product management. You can read more from Pat at the Engineering & Leadership blog.
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