Innovation Tools and Continuous Improvement Evaluations

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    "Is TRIZ the best innovation methology? TRIZ is a collection of tools that are leveraged to repeatably, predictably and reliably converge on an idea that achieves the specified purpose while minimizing trade-offs in the system."

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    By Odair Oliva de Farias, Wellington Barros Bonfim Filho and Edgardo Córdova López

    Abstract

    Quality and innovation are key issues in today's businesses and managers are focusing on special tools to improve their results, including the Theory of Inventive Problem Solving (TRIZ). This study identifies negative and positive aspects of these tools, while evaluating facilities and effective results during their implementation and application, suggesting some ways of improving these technological resources. There are some contributions regarding the natural evolution of companies' innovation processes and the benefits of utilizing TRIZ methods in these processes. 

    Introduction

    Companies have had to look for resources and tools that enable innovative problem solving and improve general processes with the challenges of a global economy and a paradigm break from competition to competitiveness. Innovation, unfortunately, has limits – lifestyle, technology, regulations, etc.1

    There are distinctions between continuous improvement and innovation efforts – incremental innovation can refer to continuous improvement and radical innovation refers to complete changes in the way of doing things. But the distinction between incremental and radical is deliberately vague, as it is intended to include continuous improvement and innovation under the one heading; the line between the two is sometimes blurred and difficult to define. All forms of innovation fit within the definition, as does the implementation of ideas acquired from knowledge sharing or best practice learning. It is not improvement that is important, but the momentum of the improvement itself. It is necessary that each stage improves and has positive results, especially when it comes to saving/making money.4

    TRIZ, in conjunction with models of process improvement, is an effective resource for improvement.

    Innovation Process

    Tools that support the innovation process (including TRIZ tools) are specifically oriented toward the inventive principles as shown in Figure 1.

     Figure 1: Improvements Directed by Inventive Principles

    In theory, any process or result can be improved as can any line on a financial statement. In the 21st century specific items are key focuses of continuous improvement – productivity, efficiency, quality, revenue and costs – that can be analyzed by TRIZ by using, for example, the contradiction matrix.3 A continuous improvement process offers additional benefits: performance advantage through improved organizational capabilities, alignment of improvement activities at all levels to an organization's strategic intent, and flexibility to react quickly to opportunities.

    Among researched tools this article emphasizes the contradiction matrix (TRIZ), Su-field system (TRIZ), Six Sigma, fishbone (Ishikawa), Lean models, brainstorming, prioritizing matrix, simulations and total productive maintenance (TPM). To better understand each tool's contributions toward continuous improvement process the characteristics of each method are described in terms of how they foster innovation. The tools are then evaluated from a TRIZ perspective. For this research a detailed evaluation of the minimum requirements and the general performance of software supporting TRIZ were used.

    TRIZ-based Tools

    Because the majority of problems in a contemporary company are not linear and demand ample analysis of trade-offs, the majority of possible solutions are also limited. TRIZ supports decision making and direct improvement steps. Prioritizing processes such as quality, costs, supply and risk management facilitates incremental innovation. By attributing weights to the selected priority processes it is possible to identify (through mathematical functions) idealist relationships of the average standards, and the best actions and initiatives of the identified inventive principles. In turn, such initiatives must be implemented in the processes that initially originated the contradictions – closing a cycle of revision and improvement.

    Methodological Procedures

    To evaluate the software programs suppliers, the authors used a Likert scale (ranking items from 1 to 5) to assess how well the customers' requirements were being met. Sixteen parameters were evaluated:

    Table 1: Evaluation of the Software Programs Suppliers 
    Use Facilities Resource Effectiveness 
    Software investment (Si) Results clarity (Rc) 
    Training investment (Ti) Problems' adherence (Pa) 
    Internal coaching needs (Ic) Solution specificity (Ss)
    External coaching needs (Ec) Direct contribution (Dc) 
    Use complexity (Uc)Indirect contribution (Ic) 
    Implementation facility (If)Analysis facility (Af) 
    Continuous use facility (Uf)Graphic reproducibility (Gr) 
    Users interest level (Ui)Revision needs (Rn)

    Each group of parameters must be reduced by a factorial analysis of at least two factors – ease of use and effectiveness of the information technology (IT) resource. From this it is necessary to analyze which parameters contribute to the improved performance of the solutions (suggested by the software). Beyond quantitative analysis, the work builds on the specific demands of the departments – related to the innovation as the departments of production and development, continuous improvement, quality, processes and others. With the detailing of some of the solutions evaluated in the research, it is possible to identify the main areas of performance that have needs for innovation. In the same way it verified the possibility of such solutions to meet these demands in different departments in the same company. Businesses enumerate the solutions (already presented by specialists in TRIZ) and the description of positive results in great companies in different countries – the methodology can be used to support innovation in a multi-disciplinary international field.

    Other characteristics of the innovation tools must explore the languages commonly used, the portability of the systems with conventional systems and the algorithms that are normally used to compile information and generate satisfactory results – Table 2 displays the interface used. Each one of these characteristics must be explored to understand the assumptions in the profile. In reality it is about the construction of an "innovative world," in the age where the best inventive standards will become worldwide standards.

    Empirical Results and Comments

    The research was conduced by listening to 11 specialists involved with the development of TRIZ-based tools. Their opinions about tools in use around the world are presented in the following table:      

    Table 2: Empirical Results 
    TBT ResearchTBT A TBT BTBT CTBT DTBT ETBT FTBT GTBT HTBT ITBT JTBT KAverage 
    Software investment3.45
    Training investment 3.27 
    Internal coaching needs  3.36 
    External coaching needs 3.73 
    Use complexity4.00 
    Implementation facility434.18
    Continuous use facility4.45 
    Users interest level543.91 
    Average 3.80 
    Results clarity3.27 
    Problems' adherence3.45 
    Solution specificity3.73 
    Direct contribution3.73 
    Indirect contribution3.36 
    Analysis facility3.73 
    Graphic reproducibility3.09 
    Revision needs3.73 
    Average 3.51 
     *Likert Scale 1 to 5 (low to high)                                 TBT = TRIZ-based Tool

    Although not all companies have experience with all tools, some companies have experience with a large number of methods using innovation software. The use of TRIZ (integrated with any kind of quality solutions) takes problem solving, process improvement and strategic planning to higher efficiency levels.2 Suppliers from five countries participated in the study and contributed to the research regarding process, products and services innovation. Although the article describes the profile of each technology, it preserves the anonymity of its suppliers in order to promote an impartial discussion. Statistical analysis could be performed in order to reduce the selection of parameters.

    Exploratory research can take several forms. The quantitative research was conducted using an interval scale according to the satisfaction degree – a metric scale as a summed Likert where value 1 corresponds to "totally dissatisfactory" and value 5 corresponds to "totally satisfied." To analyze the data and reduce the independent variables the authors used SPSS software (Version 15.0) through factorial analysis with principal and Varimax methods.

    Some specific results are shown in Table 3 and Table 4. 

    Table 3: Principal Component Analysis Rotation Method: Varimax with Kaiser Normalization  
     Component 1 Component 2 
    Custos  .292 
    Custos  .459 
    RH  .335 
    RH .221  
    Complexity .249  
    Facility .235  
    Facility .226  
    Interest .178  

    Table 4: Principal Component Analysis Rotation Method: Varimax with Kaiser Normalization 
     Component 1 Component 2 
    Clarity  .650 
    Adherence  .827 
    Specificity .814  
    Contribution .849  
    Individual contribution  .922 
    Facility .862  
    Graphic reproducibility .756  
    Revision .904  

              

     

     
     
      
       




     

     

     

    With this multi-variant analysis the study confirmed four different constructs – two for each analysis. The data could be divided separating investments and coaching needs as an integration need, and facilities and complexities as implementation needs. In case of its effectiveness it could also be divided separating results clarity and reproducibility as adherence and contributions, or analysis facilities.

    Table 5: Variance Analysis 
     Initial Eigenvalues Extraction Sums of Squared Loadings 
    Component Total % of Variance Cumulative % Total % of Variance Cumulative % 
    3.827   47.839 47.839  3.827  47.839  47.839
     1.798 22.473   70.312  1.798 22.473  70.312 
     Initial Eigenvalues Extraction Sums of Squared Loadings 
    Component Total % of Variance Cumulative % Total % of Variance Cumulative % 
    3.954 49.427 49.427 3.954 49.427 49.427 
    2.027 25.342 74.7692.02725.34274.769

    Conclusions

    The analysis performed in this study showed that TRIZ-based solutions represent an important investment as does initial training. This kind of issue appears to have been addressed in the latest developed solutions, especially those structured by Web 2.0 architecture. After integration, the experience usually occurs as a light implementation with relatively low complexity. There was a consistent contribution between the main tools throughout general projects, but as in the research results some improvements could be obtained by increasing the solutions adherence for each specific sector, and innovative ways of using graphics representation.

    Among the main limitations of the research is the difficulty of carrying through the separate analysis for each area of performance. Some peculiarities exist throughout the work. As a proposal for future studies the authors consider the detailing of the solutions most accepted in the market exploring the challenges of the implementation, the maintenance of interfaces and the interpretation of results.

    References

    1. Hamel, G. et al (1998) Repensando o Futuro. Makron Books, São Paulo, page 60.
    2. Smith, L.R. (2006) Higher Ground: An Integration of Innovation and Quality Technology. TRIZ Futures Conference, Kortrijk, Belgium.
    3. Mann, D. (2001) Hands-On Systematic Innovation. London, Creax.
    4. Slack, N. (2002) Administração da Produção, Editora Atlas, São Paulo, page 603.
    5. López, Edgardo Córdova, Contribution a une Approche Méthodologique du Processus d'innovation: Application de la Théorie Triz Aux Systèmes Produit-Procédé- Processus/ Doctoral these presented July 16, 2002 in the Institute National Polytechnique de Toulouse, France.

    Note: This paper was presented at 2º Congreso Iberoamericano de Innovación Tecnológica Monterrey, N.L. 30 de octubre al 1 de noviembre de 2007.

    About the Authors:

    Odair Oliva de Farias has a master's degree in administration and operations, is a teacher at the Catholic University of Santos and the University of Santo André. De Farias is also one of the directors of Log1 Consulting, in the areas of logistitics, production, innovation, supply-chain and planning. Contact Odair Oliva de Farias at odair (at) log1consulting.com.

    Wellington Barros Bonfim Filho studied logistics and transportation at FATEC-BS. A TRIZ reseacher since 2004, Mr. Filho is a director of Log1 Consulting. Contact Wellington Barros Bonfim Filho at wellington (at) log1consulting.com.

    Edgardo Córdova López is Vice-president of AMETRIZ in México and a researcher for the University of Puebla (BUAP). Contact Edgardo Córdova López at ecordoval (at) yahoo.com.

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