Overview
You work as a middle manager for one of the top U.S. producers of luxury and mass-market automobiles and trucks. In response to a VUCA (volatile, uncertain, complex, and ambiguous) world, innovation has become a necessity for most organizations that want to compete in the marketplace. This includes automobile and truck manufacturers. The organization from the course scenario has decided to add IoT technology to its vehicles. While the organization is debating whether to utilize incremental or discontinuous innovation, you have been asked to create a presentation analyzing the dimensions of innovation for your team members. This presentation will help your team members understand the potential options for the organization and the possible technological trajectory (path).
Prompt
Using the information in the overview above and reviewing dimensions of innovation and the five major technological trajectories from your textbook, create a presentation analyzing innovations. It may be helpful to review the CTO Brief, Comparative Growth Data, Comparative Operating Statistics, and Comparative Product Plans documents. Your presentation should include the following points:
- Slide One: Give examples of types of innovation for your company at the component and system levels.
- Slide Two: Describe the potential incremental innovations from the types of innovation and explain why they are incremental.
- Slide Three: Describe the potential discontinuous innovations from the types of innovation and explain why they are discontinuous.
- Slides Four/Five: Explain the potential path for your organization by identifying one of the five technological trajectories for your organization along with your justification for that choice.
Guidelines for Submission
Using PowerPoint, create a 4–5 slide presentation that includes detailed speaker notes highlighting the important points you want to emphasize to your team members and includes references cited in APA format. Consult the Shapiro Library APA Style Guide for more information on citations.
CriteriaExemplary (100%)Proficient (90%)Needs Improvement (70%)Not Evident (0%)Value
Types of Innovation
Exceeds proficiency in an exceptionally clear, insightful, sophisticated, or creative manner
Identifies types of innovation clearly for the company at the component level and system level
Shows progress toward proficiency, but with errors or omissions; areas for improvement may include identifying the component and system levels
Does not attempt criterion
30
Potential Incremental Innovations
Exceeds proficiency in an exceptionally clear, insightful, sophisticated, or creative manner
Explains why the identified types of innovation are incremental
Shows progress toward proficiency, but with errors or omissions; areas for improvement may include accurately identifying the type of innovation as incremental
Does not attempt criterion
10
Potential Discontinuous Innovations
Exceeds proficiency in an exceptionally clear, insightful, sophisticated, or creative manner
Explains why the identified types of innovation are discontinuous
Shows progress toward proficiency, but with errors or omissions; areas for improvement may include accurately identifying the type of innovation as discontinuous
Does not attempt criterion
10
Path for Organization
Exceeds proficiency in an exceptionally clear, insightful, sophisticated, or creative manner
Identifies a potential path for the organization including the selection and justification of using one of the five technological trajectories
Shows progress toward proficiency, but with errors or omissions; areas for improvement may include adding a justification of the selection of technological trajectory
Does not attempt criterion
30
Citations and Attributions
Uses citations for ideas requiring attribution, with few or no minor errors
Uses citations for ideas requiring attribution, with consistent minor errors
Uses citations for ideas requiring attribution, with major errors
Does not use citations for ideas requiring attribution
10
Articulation of Response
Exceeds proficiency in an exceptionally clear, insightful, sophisticated, or creative manner
Clearly conveys meaning with correct grammar, sentence structure, and spelling, demonstrating an understanding of audience and purpose
Shows progress toward proficiency, but with errors in grammar, sentence structure, and spelling, negatively impacting readability
Submission has critical errors in grammar, sentence structure, and spelling, preventing understanding of ideas
10
Total100%
MBA 580 Chief Technology Officer (CTO) Brief
Over the past three decades, sensors have been increasingly integrated into automobiles. Currently, a
typical car has 50–100 sensors (Tyler, 2016), and this is expected to grow to as many as 200 over the
next few years. These sensors measure everything from oil levels to the distance from the car in front.
These sensors currently connect (Computers in Your Car, 2018). These computer systems can warn of a
collision or an engine problem and communicate the condition to the driver (e.g., turn on the check
engine light).
Increasingly, these computers are connected wirelessly via the internet to other computers, like the
user’s phone for things like remote starting, and to the manufacturer to help generate predictive
maintenance recommendations. The commercial term currently used for this is connected cars.
Technically, this is part of the internet of things (IoT) concept—where devices from refrigerators to door
locks are connected via the internet for convenient access by the user from phones, computers, and
personal automobiles.
Currently, and in the immediate future, connected cars will help the driver navigate, find the cheapest
gas station, locate the nearest Starbucks or parking lot with open spaces, and allow friends on social
media to know when their friend will arrive. As more semi-autonomous driving features are added over
the next few years, these wireless computers will also talk to other cars to help predict their next move
and communicate to road sensors to monitor conditions (Gossett, 2019). Eventually, enough
information will be provided to and from the connected car that autonomous driving will become
commonplace.
It is estimated that the market for IoT-connected cars will grow from $54 billion in 2019 to over $510
billion by 2030 at a 25% compound annual growth rate (CAGR) (Meola, 2020). This compares with an
overall industry growth of 4.1% (The Global Automotive Motors Market Size Is Projected to Grow from
USD 20,321 Million in 2020 to USD 25,719 Million by 2025, at a CAGR of 4.8%, 2020).
Our company is marketing some connected car capability—but we are not the leader. We need to
innovate so that our products can be competitive in the rapidly growing market. Our cars have sensors
and computers, and our technology expertise is competitive. We have some connectivity—driver apps
for keyless start and OnStar (The Benefits of OnStar | Keeping You Safe and Secure, n.d.) connectivity to
detect accidents and alert first responders. Our growth and ultimate health as an enterprise depends on
us taking the leadership or, at least, keeping up with the leaders. Furthermore, there is significant
opportunity to improve our customer satisfaction and increase our repair and parts revenue streams by
alerting customers to needed maintenance before an expensive breakdown occurs on the road.
With our current technology implementation plan, however, we expect to grow at 3.1%, about 1% less
than the industry. Our growth projection for connected cars is 10.2%—less than the industry at large.
We must speed up our innovation or risk losing market share.
Here is what we estimate our competitors are doing and how fast they are adding technology. The
leader among existing auto manufacturers is BMW. BMW cars have significant connectivity to
information services now. Some driver-assist functions, such as auto-parking and lane-keeping, have
been in BMW models for several years. Market research suggests that BMW will have a full suite of
information connectivity in their cars within several years and that the company will begin producing
fully autonomous driving machines within 12 years. Toyota has fully integrated social media in Japan
and expects to implement it in European and U.S. markets, subject to 5G wireless availability.
Volkswagen is about where we are—but has partnered with Microsoft to jump ahead.
Competitors from outside the traditional automobile manufacturers are also indicating that they intend
to enter the connected car market with disruptive technologies. Apple, for example, is aiming for a fully
autonomous delivery vehicle by the mid-2020s and an autonomous passenger car within a decade.
Our goal is to launch an autonomous vehicle following quickly after BMW, our main luxury competitor.
However, we have a long way to go. We are considering two ways to get there: A) Introducing a radical
innovative design in several years or B) Introducing incremental improvements faster than we have in
the past and improving our current models each year. Option A does not prevent us from continuing to
introduce incremental improvements in the interim.
Our approach will depend on your analysis of our capabilities to innovate. How can we get the
technology being researched in our lab ready—how can we develop it, produce it, and take it to market?
What technology do we already have, and what will we need to acquire? What are our competitors
doing, and are there weaknesses we can exploit?
The two paths we can take are discontinuous or radical innovation, or incremental innovation.
What do I mean by this?
Discontinuous or radical innovation. This would be more expensive—a completely new model is
expensive—as much as $6 billion (Viswanathan, 2013). A major redesign and recent technology
integration are also riskier to develop—we might fail—and it would take longer to get to market.
We might require enough of our existing resources that we could fall behind with our current
models, but it also might provide insight in incremental changes to current models while we
developed a major new product line. It is a lot to think about. That said, we could take the
leadership position ourselves in the growing market and better protect ourselves from
competitors. If we took this path, we would first introduce a new high-end model and, as we
brought costs down, rapidly deploy it across our whole product line, using this innovation
process to accelerate our ability to innovate.
Incremental innovation. The automobile is a mature technology—the modern automobile is
over a century old and it has been changing and adapting over that time. Our company does
incremental innovation as well as our major competitors and the costs are built into our way of
doing business. Given how we build automobiles today, we can continue to add sensors,
computers, and IoT capabilities each model year just by upgrading modules. There are risks,
though: 1) Could changes in the market impact what customers demand? A faster competitor or
a new entrant could produce a breakthrough in automobiles that makes everything else
obsolete. It has happened in other mature industries—could it happen here? 2) Are we missing
significant new opportunities (e.g., market growth overall or opportunities in integrated
maintenance, service revenues and parts, or a high-margin business) that we do not control
now?
References:
Tyler, N. (2016, December 14). Demand for automotive sensors is booming. Newelectronics.Co.Uk.
https://www.newelectronics.co.uk/electronics-technology/automotive-sensors-market-is-
booming/149323/#:%7E:text=Currently%2C%20each%20vehicle%20has%20from,car%20based%
20on%20current%20trends
Computers in your car. (2018, January 24). AAMCO Colorado.
https://www.aamcocolorado.com/computers-in-your-
car/#:%7E:text=Your%20Car’s%20Computer,controls%20to%20meet%20emissions%20standard
s
Gossett, S. (2019, August 13). IoT in vehicles: A brief overview. Built In. https://builtin.com/internet-
things/iot-in-vehicles
Meola, A. (2020, March 10). How 5G & IoT technologies are driving the connected smart vehicle industry.
Business Insider. https://www.businessinsider.com/iot-connected-smart-
cars?international=true&r=US&IR=T
The global automotive motors market size is projected to grow from USD 20,321 million in 2020 to USD
25,719 million by 2025, at a CAGR of 4.8%. (2020, August 17). PR Newswire.
https://www.prnewswire.com/news-releases/the-global-automotive-motors-market-size-is-
projected-to-grow-from-usd-20-321-million-in-2020-to-usd-25-719-million-by-2025–at-a-cagr-
of-4-8-301113089.html#:%7E:text=%2F%3Futm_source%3DPRN-
,The%20global%20automotive%20motors%20market%20size%20is%20projected%20to%20gro
w,at%20a%20CAGR%20of%204.8%25.&text=The%20growing%20adoption%20of%20these,dem
and%20for%20safety%20and%20convenience
The benefits of OnStar | Keeping you safe and secure. (n.d.). OnStar.
https://www.onstar.com/us/en/why-onstar/
Viswanathan, B. (2013, May 7). Why are cars not getting cheap even with better economies of scale?
Forbes. https://www.forbes.com/sites/quora/2013/05/07/why-are-cars-not-getting-cheap-
even-with-better-economies-of-scale/?sh=3ad2b1045ad9
in
| Markets and Competitors | Annual Cars & Light Trucks Revenue in 2020 (billions) TAM | Market share percentage for cars and trucks now | Projected CAGR over the next 10 years | Projected revenues in 2030 (billions) | Market share percentage for cars and trucks in 2030 | Global Market for Connected Cars & Light Trucks (billions) TAM | Market share percentage for connected cars and trucks now | CAGR over next 10 years | Projected Conencted Car Revenues (billions) in 2030 | Market share percentage for connected cars and trucks in 2030 |
| Global | $ 3,227.70 | 100% | 4.10% | $ 4,810.0 | 100% | 53.9 | 100% | 25.20% | $ 510.07 | 100% |
| Your Company | $ 187.10 | 5.80% | 3.10% | $ 254.2 | 5.28% | 3.83 | 7.10% | 10.20% | $ 10.11 | 1.98% |
| BMW | $ 126.10 | 3.91% | 3.70% | $ 181.5 | 3.77% | 1.62 | 3.00% | 25.50% | $ 15.67 | 3.07% |
| Toyota | $ 275.40 | 8.53% | 3.90% | $ 404.5 | 8.41% | 4.80 | 8.90% | 24.80% | $ 43.97 | 8.62% |
| VW | $ 282.90 | 8.76% | 4.30% | $ 433.1 | 9.00% | 8.36 | 15.50% | 23.20% | $ 67.30 | 13.19% |
| Note for student: Projected Global revenue for in-car connected services by 2030: $81.1 Billion | ||||||||||
in
| in billions USD | ||||
| Your Company | VW | BMW | Toyota | |
| Revenue | 187.1 | 282.9 | 126.1 | 275.4 |
| Operating Income | 5.7 | 20.5 | 9 | 22.5 |
| Net Income | 0.9 | 16.1 | 6.1 | 19.7 |
| Assets | 310 | 590.6 | 275.9 | 484.7 |
| Liabilities | 270.2 | 443.2 | 203.4 | 293.9 |
| Equity | 39.9 | 147.4 | 72.5 | 190.8 |
| Number Employees | 190,000 | 304,174 | 133,778 | 359,542 |
| Notes: | ||||
| 1 Euro = 1.21 USD | ||||
| 1 Yen = 0.0094 USD | 0.0092 | |||
| references: | ||||
| Full Speed Ahead To The Future. 2019 Annual Report”. Volkswagen Group. 17 March 2020. Retrieved 17 March 2020. | ||||
| converstion rages via Morningstar | ||||
| Annual Report 2019″ (PDF). BMW Group. Retrieved 19 March 2020. | ||||
| Toyota Annual Report 2020″ (PDF). Toyota Motor Corporation. May 12, 2020. | ||||
| Ford Motor Company 2019 Annual Report (Form 10-K)”(PDF). sec.gov. U.S. Securities and Exchange Commission. January 2020. Note: numbers disguised by multiplying by 1.12 except for operating income multiplied by 10 and net income multiplied by20 |
||||
Comparative Product Plans
| Company | Number of Sensors and Computers by 2025 |
Functionality Emphasis | Current Connected Services | 5–10 Year Product Plans | Existing Partnerships |
| Your Company | 65 sensors/30 computers | vehicle control, systems maintenance, entertainment, navigation, 5G | navigation, emergency services, service status | fully integrated information system, assisted driving, expanded service information, semi-autonomous vehicle within 10 years | Toyota, Waymo |
| BMW | 125 sensors/50 computers | vehicle control/safety, IFTTT-customized applications and IoT connectivity, LTE | navigation, emergency services, smart house connectivity | fully integrated information system, semi-autonomous driving, connection to traffic information systems, introduction of fully autonomous driving early 2030s | Daimler |
| Toyota | 100 sensors/40 computers | vehicle control, social media, safety, entertainment, navigation, 5G | navigation, emergency services, social media | fully integrated information system; semi-autonomous driving; connection to traffic information systems, expanded social media, and communications; consumer services; maintenance; fully autonomous vehicle early 2030s | Microsoft, Ford |
| VW | 90 sensors/35 computers | vehicle control, maintenance, in-car consumer experience | navigation, emergency services, consumer orders, maintenance status | fully integrated information system; semi-autonomous driving; connection to traffic information systems; connectivity with smart home; fully autonomous vehicle early 2030s | Microsoft |
| References: | |||||
| https://medium.com/@water.street/autonomous-vehicle-partnerships-how-tech-companies-and-automakers-are-collaborating-to-innovate-cf44bc9e85a | |||||
| https://techcrunch.com/2019/07/04/bmw-and-daimler-partner-on-autonomous-driving-first-results-of-team-up-in-market-by-2024/ | |||||
