1. Innovation vs. Invention
Creation of something new
Innovation
Both creation/adoption and implementation

2. Organization and Innovation
Organic
Encourage bottom-up innovation process
May not be the best structure for production
Mechanistic
Emphasis on rules and regulations
Very good structure for producing routine products
Ambidextrous
Organic for innovation, mechanistic for production

3. Sequence of Elements for Successful Change
Environment
Internal
Creativity and
Inventions
Suppliers
Professional
Associations
Consultants
Research
literature
Organization
1. Ideas
3. Adoption
4.Implementation
2. Needs
Customers
Competition
Legislation
Regulation
Labor force
5. Resources
Perceived
Problems or
Opportunities

4. Techniques for Encouraging Technology Change
Switching Structures
Creative Departments
Venture Teams
Corporate Entrepreneurship

5. Probability of New Product Success
Technical completion
(technical objectives achieved) .57
Commercialization
(full-scale marketing) .31
Market Success
(earns economic returns) .12
Source: Based on Edwin Mansfield, J. Rapaport, J. Schnee,
S. Wagner, and M. Hamburger, Research and Innovation in
Modern Corporations (New York: Norton, 1971), 57.

6. Components for Innovation Success
Specialization
Boundary Spanning
Horizontal Linkages
These components are called the Horizontal Linkages Model.

7. Horizontal Linkages Model
Environment
Organization
Environment
General
Manager
Technical
Developments
Customer
Needs
Linkage
R&D
Department
Linkage
Marketing
Department
Linkage
Linkage
Linkage
Production
Department

8. The Need for Speed
The ability to rapidly develop new products is a strategic weapon in today’s marketplace.
Time-based competition

9. Separate boundary roles Geographical dispersion
Structural Characteristics of Service Organizations vs. Product Organizations
Service
Product
Structure:
Separate boundary roles
Few
Many
Geographical dispersion
Much
Little
Decision making
Decentralized
Centralized
Formalization
Lower
Higher
Human Resources:
Employee skill level
Skill emphasis
Interpersonal
Technical

10. Relationship of Department Technology to Structural and Management Characteristics
Low
Mostly Organic Structure
1. Moderate formalization
2. Moderate centralization
3. Work experience
4. Moderate to wide span
5. Horizontal, verbal
communications
CRAFT
Organic Structure
1. Low formalization
2. Low centralization
3. Training plus experience
4. Moderate to narrow span
5. Horizontal communications
meetings
NONROUTINE
Analyzability
Mechanistic Structure
1. High formalization
2. High centralization
3. Little training or experience
4. Wide span
5. Vertical, written
communications
ROUTINE
Mostly Mechanistic Structure
1. Moderate formalization
2. Moderate centralization
3. Formal training
4. Moderate span
5. Written and verbal
communications
ENGINEERING
High
Low
High
Variety

11. Craft Department Technologies
Mostly Organic Structure
1. Moderate formalization
2. Moderate centralization
3. Work experience
4. Moderate to wide span
5. Horizontal, verbal
communications
CRAFT
Craft
Low analyzability
Low variety
Requires extensive training and experience
Technology has significantly reduced number of craft organizations
Examples
Performing arts
Trades
Fine goods manufacturing
Organic Structure
1. Low formalization
2. Low centralization
3. Training plus experience
4. Moderate to narrow span
5. Horizontal communications
meetings
NONROUTINE
Mechanistic Structure
1. High formalization
2. High centralization
3. Little training or experience
4. Wide span
5. Vertical, written
communications
ROUTINE
Mostly Mechanistic Structure
1. Moderate formalization
2. Moderate centralization
3. Formal training
4. Moderate span
5. Written and verbal
communications
ENGINEERING

12. Non Routine Department Technologies
Low analyzability
High variety
Great deal of effort devoted to analyzing problems and activities
Experience and technical knowledge used to solve problems and perform work
Examples
Strategic planning
Social science research
Applied research
Mostly Organic Structure
1. Moderate formalization
2. Moderate centralization
3. Work experience
4. Moderate to wide span
5. Horizontal, verbal
communications
CRAFT
Organic Structure
1. Low formalization
2. Low centralization
3. Training plus experience
4. Moderate to narrow span
5. Horizontal communications
meetings
NONROUTINE
Mechanistic Structure
1. High formalization
2. High centralization
3. Little training or experience
4. Wide span
5. Vertical, written
communications
ROUTINE
Mostly Mechanistic Structure
1. Moderate formalization
2. Moderate centralization
3. Formal training
4. Moderate span
5. Written and verbal
communications
ENGINEERING

13. Routine Department Technologies
Mostly Organic Structure
1. Moderate formalization
2. Moderate centralization
3. Work experience
4. Moderate to wide span
5. Horizontal, verbal
communications
CRAFT
Routine
High analyzability
Low variety
Broad applications for standard work instructions
Significant use of objective and computational procedures
Examples
Sales
Clerical
Drafting
Auditing
Organic Structure
1. Low formalization
2. Low centralization
3. Training plus experience
4. Moderate to narrow span
5. Horizontal communications
meetings
NONROUTINE
Mechanistic Structure
1. High formalization
2. High centralization
3. Little training or experience
4. Wide span
5. Vertical, written
communications
ROUTINE
Mostly Mechanistic Structure
1. Moderate formalization
2. Moderate centralization
3. Formal training
4. Moderate span
5. Written and verbal
communications
ENGINEERING

14. Engineering Department Technologies
High analyzability
High variety
Activities handled on basis of established formulas, procedures, and techniques
Refer to well-established bodies of knowledge in performing tasks
Examples
Legal
Tax accounting
General accounting
Mostly Organic Structure
1. Moderate formalization
2. Moderate centralization
3. Work experience
4. Moderate to wide span
5. Horizontal, verbal
communications
CRAFT
Organic Structure
1. Low formalization
2. Low centralization
3. Training plus experience
4. Moderate to narrow span
5. Horizontal communications
meetings
NONROUTINE
Mechanistic Structure
1. High formalization
2. High centralization
3. Little training or experience
4. Wide span
5. Vertical, written
communications
ROUTINE
Mostly Mechanistic Structure
1. Moderate formalization
2. Moderate centralization
3. Formal training
4. Moderate span
5. Written and verbal
communications
ENGINEERING

15. Sociotechnical Systems Model
The Social System
Individual and team
behaviors
Organizational/team
culture
Management practices
Leadership style
Degree of communication
and openness
Individual needs and
desires
The Technical System
Type of production
technology (small batch,
mass production, FMS, etc.)
Level of interdependence
(pooled, sequential,
reciprocal)
Physical work setting
Complexity of production
process (variety and
analyzability)
Nature of raw materials
Time pressure
Design for
Joint Optimization
Work roles, tasks,
workflow
Goals and values
Skills and abilities

16. Coercive vs. Enabling Organizations
Are all bureaucracies the same? Are all organic organizations the same?
High
Bureaucracy
Low
Coercive
Enabling
Organic
Coercive Bureaucracy
Enabling Bureaucracy
Empowered employees
Minimum rules & procedures
Little hierarchy
Rules & procedures as enabling tools
Hierarchy supports organizational learning
Autocratic
Rigid rule enforcement
Extensive written rules & procedures
Hierarchy controls
Top down control
Minimum written rules & procedures
Technical Structure
Social Structure
Source: Adapted from P.S. Adler, “Building Better Bureaucracies,” Academy of Management Executive, 13:4, November, 1999,

17. Coercive vs. Enabling Organizations
Coercive Systems and Procedures
Enabling Systems and Procedures
Systems focus on performance standards so as to highlight poor performance.
Focus on best practice methods:information on performance standards is not much use without information on best practices for achieving them.
Standardize the systems to minimize gameplaying and monitoring costs.
Systems should allow customization to different levels of skill/experience and should guide flexible improvisation.
Systems should be designed so as to keep employees out of the control loop.
Systems should help people control their own work: help them form mental models of the system by “glass box” design.
Systems are instructions to be followed, not challenged.
Systems are best practice templates to be improved.
Source: P.S. Adler, “Building Better Bureaucracies,” Academy of Management Executive,
13:4, November, 1999,

18. Two Models of Design Iterative Model synthesize analyze modify
Convergent Model 3

19. Point-Based Serial Engineering
styling
marketing
body
chassis
manufacturing
etc.     
Point-Based Concurrent Engineering: Styling Example
marketing
body
Design Solution
Analyze & Critique
chassis
Modify
manufacturing
Styling 4

20. Set-Based Concurrent Engineering
Subsystem 1
Subsystem 2
Manufacturing System
Designs converge in parallel 5

21. ? A Simple Example Set up a meeting using the point-based model.
B: No, 3:00 is bad. 9:00?
A: My best time is 10:00. Can you make it? ?
A: Uh, already booked. Can you meet at 3:00?
B: No, I can’t. How about 2:00? 6

22. A Set-Based Approach
Now set up the meeting by communicating about sets.
A: I can meet 10:00 - 1:00 or 3:00 - 5:00. Can you make any of these times?
B: Let’s meet 12:00 - 1:00. 7

23. Exercise: Technology Comparison
McDonald’s
Subway
Family Restaurant
Organization Goals
Authority Structure
Mechanistic vs. Organic
Teamwork vs. Individual
Interdependence
Routine vs. Non-routine tasks
Task Specialization
Task Standardization
Technical vs. Social Expertise
Centralized vs. Decentralized

24. For Review Questions
How does the framework we choose impact our decision making as engineering managers?
Can we truly be engineering managers if innovation is not part of our framework? Why or why not?